vol.50 no.2 june 2016 Prva in edina samostojna kemoterapija, ki v primerjavi z ostalimi možnostmi zdravljenja z enim zdravilom, pri bolnicah s predhodno že večkratno zdravljenim metastatskim rakom dojke, dokazano značilno podaljša celokupno preživetje.1,2 NOVA SMER DO PODALJŠANJA CELOKUPNEGA PREŽIVETJA Halaven (eribulin): ne-taksanski zaviralec dinamike mikrotubulov, prvo zdravilo iz nove skupine kemoterapevtikov, imenovanih halihondrini. Zdravilo HALAVEN je indicirano za zdravljenje bolnic z lokalno napredovalim ali metastatskim rakom dojke, ki je napredoval po vsaj enem režimu kemoterapije za napredovalo bolezen. Predhodna zdravljenja morajo vključevati antraciklin in taksan, bodisi kot adjuvantno zdravljenje ali za zdravljenje metastatskega raka dojke, razen če to zdravljenje za bolnice ni bilo primerno.1 Priporočeni odmerek 1,23 mg/m2, intravensko, v obliki 2-do 5-minutne infuzije, 1. in 8. dan vsakega 21-dnevnega cikla. Ena 2 ml viala vsebuje 0,88 mg eribulina. Raztopina, pripravljena za uporabo, redčenje ni potrebno. SKRAJŠAN POVZETEK GLAVNIH ZNAČILNOSTI ZDRAVILA HALAVEN 0,44 mg/ml raztopina za injiciranje (eribulin) TERAPEV TSKE INDIKACIJE: Zdravljenje lokalno napredovalega ali metastatskega raka dojke, ki je napredoval po vsaj enem režimu kemoterapije za napredovalo bolezen vključno z antraciklinom in taksanom (adjuvantno zdravljenje ali zdravljenje metastatskega raka dojke), razen če to ni bilo primerno. ODMERJANJE IN NAČIN UPORABE: Halaven se daje v enotah, specializiranih za dajanje citotoksične kemoterapije, in le pod nadzorom usposobljenega zdravnika z izkušnjami v uporabi citotoksičnih zdravil. Odmerjanje: Priporočeni odmerek eribulina v obliki raztopine je 1,23 mg/m2 i.v. v obliki 2- do 5-minutne infuzije 1. in 8. dan vsakega 21-dnevnega cikla. Bolnikom je lahko slabo ali bruhajo. Treba je razmisliti o antiemetični profilaksi, vključno s kortikosteroidi. Preložitev odmerka med zdravljenjem: Dajanje Halavena je treba preložiti, če se pojavi kaj od naslednjega: absolutno število nevtrofilcev (ANC) < 1 x 109/l, trombociti < 75 x 109/l ali nehematološki neželeni učinki 3. ali 4. stopnje. Zmanjšanje odmerka med zdravljenjem: Za priporočila za zmanjšanje odmerka ob pojavu hematoloških ali nehematoloških neželenih učinkov glejte celoten povzetek glavnih značilnosti zdravila. Okvara jeter zaradi zasevkov: Priporočeni odmerek pri blagi okvari jeter (stopnje A po Child-Pughu) je 0,97 mg/m2 v obliki 2- do 5-minutne i.v. infuzije 1. in 8. dan 21-dnevnega cikla. Priporočeni odmerek pri zmerni okvari jeter (stopnje B po Child-Pughu) je 0,62 mg/m2 v obliki 2- do 5-minutne i.v. infuzije 1. in 8. dan 21-dnevnega cikla. Pri hudi okvari jeter (stopnje C po Child-Pughu) se pričakuje, da je treba dati še manjši odmerek eribulina. Okvara jeter zaradi ciroze: Zgornje odmerke se lahko uporabi za blago do zmerno okvaro, vendar se priporoča skrbno nadziranje, saj bo odmerke morda treba ponovno prilagoditi. Okvara ledvic: Pri hudi okvari ledvic (očistek kreatinina < 40 ml/min) bo morda treba odmerek zmanjšati. Priporoča se skrbno nadziranje varnosti. Način uporabe: Odmerek se lahko razredči z do 100 ml 0,9 % raztopine natrijevega klorida (9 mg/ml) za injiciranje. Ne sme se ga redčiti v 5 % infuzijski raztopini glukoze. Pred dajanjem glejte navodila glede redčenja zdravila v celotnem povzetku glavnih značilnosti zdravila ter se prepričajte, da obstaja dober periferni venski dostop ali prehodna centralna linija. Ni znakov, da bi eribulin povzročal mehurje ali dražil. V primeru ekstravazacije mora biti zdravljenje simptomatsko. KONTRAINDIKACIJE: Preobčutljivost na zdravilno učinkovino ali katerokoli pomožno snov. Dojenje. POSEBNA OPOZORILA IN PREVIDNOSTNI UKREPI: Mielosupresija je odvisna od odmerka in se kaže kot nevtropenija. Pred vsakim odmerkom eribulina je treba opraviti pregled celotne krvne slike. Zdravljenje z eribulinom se lahko uvede le pri bolnikih z vrednostmi ANC . 1,5 x 109/l in s trombociti > 100 x 109/l. Bolnike, pri katerih se pojavijo febrilna nevtropenija, huda nevtropenija ali trombocitopenija, je treba zdraviti v skladu s priporočili v celotnem povzetku glavnih značilnosti zdravila. Hudo nevtropenijo se lahko zdravi z uporabo G-CSF ali enakovrednim zdravilom v skladu s smernicami. Bolnike je treba skrbno nadzirati za znake periferne motorične in senzorične nevropatije. Pri razvoju hude periferne nevrotoksičnosti je treba odmerek prestaviti ali zmanjšati. Če začnemo zdravljenje pri bolnikih s kongestivnim srčnim popuščanjem, z bradiaritmijami ali sočasno z zdravili, za katera je znano, da podaljšujejo interval QT, vključno z antiaritmiki razreda Ia in III, in z elektrolitskimi motnjami, je priporočljivo spremljanje EKG. Pred začetkom zdravljenja s Halavenom je treba popraviti hipokaliemijo in hipomagneziemijo in te elektrolite je treba občasno kontrolirati med zdravljenjem. Eribulina ne smemo dajati bolnikom s prirojenim sindromom dolgega intervala QT. To zdravilo vsebuje majhne količine etanola (alkohola), manj kot 100 mg na odmerek. Eribulin je pri podganah embriotoksičen, fetotoksičen in teratogen. Halavena se ne sme uporabljati med nosečnostjo, razen kadar je to nujno potrebno. Ženske v rodni dobi naj ne zanosijo v času, ko same ali njihov moški partner dobivajo Halaven, in naj med zdravljenjem in še do 3 mesece po njem uporabljajo učinkovito kontracepcijo. Moški naj se pred zdravljenjem posvetujejo o shranjevanju sperme zaradi možnosti nepopravljive neplodnosti. INTERAKCIJE: Eribulin se izloča do 70 % prek žolča. Sočasna uporaba učinkovin, ki zavirajo jetrne transportne beljakovine, kot so beljakovine za prenos organskih anionov in beljakovine, odporne na številna zdravila, z eribulinom se ne priporoča (npr. ciklosporin, ritonavir, sakvinavir, lopinavir in nekateri drugi zaviralci proteaze, efavirenz, emtricitabin, verapamil, klaritromicin, kinin, kinidin, dizopiramid itd). Sočasno zdravljenje z indukcijskimi učinkovinami, kot so rifampicin, karbamazepin, fenitoin, šentjanževka, lahko povzroči znižanje koncentracij eribulina v plazmi, zato je ob sočasni uporabi induktorjev potrebna previdnost. Eribulin je blag inhibitor encima CYP3A4. Priporočljiva je previdnost in spremljanje glede neželenih učinkov pri sočasni uporabi snovi, ki imajo ozko terapevtsko okno in se odstranjujejo iz telesa predvsem preko CYP3A4 (npr. alfentanil, ciklosporin, ergotamin, fentanil, pimozid, kinidin, sirolimus, takrolimus). NEŽELENI UČINKI: Povzetek varnostnega profila Neželeni učinek, o katerem najpogosteje poročajo v zvezi s Halavenom, je supresija kostnega mozga, ki se kaže kot nevtropenija, levkopenija, anemija, trombocitopenija s pridruženimi okužbami. Poročali so tudi o novem začetku ali poslabšanju že obstoječe periferne nevropatije. Med neželenimi učinki, o katerih poročajo, je toksičnost za prebavila, ki se kaže kot anoreksija, navzea, bruhanje, driska, zaprtost in stomatitis. Med drugimi neželenimi učinki so utrujenost, alopecija, zvečani jetrni encimi, sepsa in mišičnoskeletni bolečinski sindrom. Seznam neželenih učinkov: Zelo pogosti (. 1/10): nevtropenija (57,0 %) (3./4. stopnje: 49,7 %), levkopenija (29,3 %) (3./4. stopnje: 17,3 %), anemija (20,6 %) (3./4. stopnje: 2,0 %), zmanjšan apetit (21,9 %) (3./4. stopnje: 0,7 %), periferna nevropatija (35,6 %) (3./4. stopnje: 7,6 %), glavobol (17,2 %) (3./4. stopnje: 0,8 %), dispnea (13,9 %) (3./4. stopnje: 3,1 %), kašelj (13,6 %) (3./4. stopnje: 0,6 %), navzea (33,8 %) (3./4. stopnje: 1,1 %), zaprtost (19,6 %) (3./4. stopnje: 0,6 %), driska (17,9 %) (3./4. stopnje: 0,8 %), bruhanje (17,6 %) (3./4. stopnje: 0,9 %), alopecija, artralgija in mialgija (19,4 %) (3./4. stopnje: 1,1 %), bolečina v hrbtu (13,0 %) (3./4. stopnje: 1,5 %), bolečina v udu (10,0 %) (3./4. stopnje: 0,7 %), utrujenost/astenija (47,9 %) (3./4. stopnje: 7,8 %), pireksija (20,4 %) (3./4. stopnje: 0,6 %), zmanjšanje telesne mase (11,3 %) (3./4. stopnje: 0,3 %). Pogosti (. 1/100 do < 1/10): okužba sečil (8 %) (3./4. stopnje: 0,5 %), pljučnica (1,2 %) (3./4. stopnje: 0,8 %), ustna kandidiaza, ustni herpes, okužba zgornjih dihal, nazofaringitis, rinitis, limfopenija (4,9 %) (3./4. stopnje: 1,4 %), febrilna nevtropenija (4,7 %) (3./4. stopnje: 4,5 %), trombocitopenija (4,3 %) (3./4. stopnje: 0,7 %), hipokaliemija (6,1 %) (3./4. stopnje: 1,7 %), hipomagneziemija (2,9 %) (3./4. stopnje: 0,2 %), dehidracija (2,8 %) (3./4. stopnje: 0,5 %), hiperglikemija, hipofosfatemija, nespečnost, depresija, disgevzija, omotičnost (7,9 %) (3./4. stopnje: 0,5 %), hipoestezija, letargija, nevrotoksičnost, obilnejše solzenje (6,0 %) (3./4. stopnje: 0,1 %), konjunktivitis, vrtoglavica, tahikardija, vročinski valovi, orofaringealna bolečina, epistaksa, rinoreja, bolečina v trebuhu, stomatitis (9,3 %) (3./4. stopnje: 0,8 %), suha usta, dispepsija (5,9 %) (3./4. stopnje: 0,2 %), gastroezofagealna refluksna bolezen, razjede v ustih, distenzija trebuha, zvišanje alanin-aminotransferaze (7,6 %) (3./4. stopnje: 2,1 %), zvišanje aspartat-aminotransferaze (7,4 %) (3./4. stopnje: 1,5 %), zvišanje gama-glutamiltransferaze (1,8 %) (3./4. stopnje: 0,9 %), hiperbilirubinemija (1,5 %) (3./4. stopnje: 0,3 %), izpuščaj, pruritus (3,9 %) (3./4. stopnje: 0,1 %), bolezni nohtov, nočno potenje, suha koža, eritem, hiperhidroza, bolečina v kosteh (9,6 %) (3./4. stopnje: 1,7 %), mišični spazmi (5,1 %) (3./4. stopnje: 0,1 %), mišično-skeletna bolečina in mišično­skeletna bolečina v prsih, mišična oslabelost, disurija, vnetje sluznice (8,3 %) (3./4. stopnje: 1,1 %), periferni edem, bolečina, mrzlica, bolečina v prsih, gripi podobna bolezen. Občasni (. 1/1.000 do < 1/100): sepsa (0,5 %) (3./4. stopnje: 0,2 %), nevtropenična sepsa (0,1 %) (3./4. stopnje: 0,1 %), herpes zoster, tinitus, globoka venska tromboza, pljučna embolija, hepatotoksičnost (1,0 %) (3./4. stopnje: 0.6 %), palmarno-plantarna eritrodisestezija, hematurija, proteinurija, odpoved ledvic. Redki (. 1/10.000 do < 1/1.000): diseminirana intravaskularna koagulacija, intersticijska pljučna bolezen, pankreatitis, angioedem. Za popoln opis neželenih učinkov glejte celoten povzetek glavnih značilnosti zdravila. Vrsta ovojnine in vsebina: viala z 2 ml raztopine. Režim izdaje: H Imetnik dovoljenja za promet: Eisai Europe Ltd, European Knowledge Centre, Mosquito Way, Hatfield, Hertfordshire, AL10 9SN, Velika Britanija HAL-270614, julij 2014 Pred predpisovanjem in uporabo zdravila prosimo preberite celoten povzetek glavnih značilnosti zdravila! Viri: (1) Povzetek glavnih značilnosti zdravila Halaven, junij 2014; (2) Cortes J et al. Lancet 2011; 377: 914–23. Odgovoren za trženje v Sloveniji: PharmaSwiss d.o.o., Brodišče 32, 1236 Trzin telefon: +386 1 236 47 00, faks: +386 1 283 38 10 HAL-0714-01, julij 2014 Publisher Association of Radiology and Oncology Affiliated with Slovenian Medical Association – Slovenian Association of Radiology, Nuclear Medicine Society, Slovenian Society for Radiotherapy and Oncology, and Slovenian Cancer Society Croatian Medical Association – Croatian Society of Radiology Societas Radiologorum Hungarorum Friuli-Venezia Giulia regional groups of S.I.R.M. Italian Society of Medical Radiology Aims and scope Radiology and Oncology is a journal devoted to publication of original contributions in diagnostic and interventional radiology, computerized tomography, ultrasound, magnetic resonance, nuclear medicine, radiotherapy, clinical and experimental oncology, radiobiology, radiophysics and radiation protection. Editor-in-Chief Gregor Serša, Institute of Oncology Ljubljana, Department of Experimental Oncology, Ljubljana, Slovenia Executive Editor Viljem Kovač, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Editorial Board Sotirios Bisdas, National Hospital for Neurology and Neurosurgery, University College London Hospitals, London, UK Karl H. Bohuslavizki, Facharzt für Nuklearmedizin, Hamburg, Germany Serena Bonin, University of Trieste, Department of Medical Sciences, Trieste, Italy Boris Brkljačić, University Hospital “Dubrava”, Department of Diagnostic and Interventional Radiology, Zagreb, Croatia Luca Campana, Veneto Institute of Oncology (IOV-IRCCS), Padova, Italy Christian Dittrich, Kaiser Franz Josef - Spital, Vienna, Austria Metka Filipič, National Institute of Biology, Department of Genetic Toxicology and Cancer Biology, Ljubljana, Slovenia Maria Gődény, National Institute of Oncology, Budapest, Hungary Janko Kos, University of Ljubljana, Faculty of Pharmacy, Ljubljana, Slovenia Robert Jeraj, University of Wisconsin, Carbone Cancer Center, Madison, Wisconsin, USA Advisory Committee Tullio Giraldi, University of Trieste, Faculty of Medicine and Psychology, Trieste, Italy Vassil Hadjidekov, Medical University, Department of Diagnostic Imaging, Sofia, Bulgaria Deputy Editors Andrej Cör, University of Primorska, Faculty of Health Science, Izola, Slovenia Maja Čemažar, Institute of Oncology Ljubljana, Department of Experimental Oncology, Ljubljana, Slovenia Igor Kocijančič, University Medical Centre Ljubljana, Institute of Radiology, Ljubljana, Slovenia Karmen Stanič, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Primož Strojan, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Tamara Lah Turnšek, National Institute of Biology, Ljubljana, Slovenia Damijan Miklavčič, University of Ljubljana, Faculty of Electrical Engineering, Ljubljana, Slovenia Luka Milas, UT M. D. Anderson Cancer Center, Houston , USA Damir Miletić, Clinical Hospital Centre Rijeka, Department of Radiology, Rijeka, Croatia Häkan Nyström, Skandionkliniken, Uppsala, Sweden Maja Osmak, Ruder Bošković Institute, Department of Molecular Biology, Zagreb, Croatia Dušan Pavčnik, Dotter Interventional Institute, Oregon Health Science Universityte, Oregon, Portland, USA Geoffrey J. Pilkington, University of Portsmouth, School of Pharmacy and Biomedical Sciences, Portsmouth, UK Ervin B. Podgoršak, McGill University, Montreal, Canada Matthew Podgorsak, Roswell Park Cancer Institute, Departments of Biophysics and Radiation Medicine, Buffalo, NY ,USA Marko Hočevar, Institute of Oncology Ljubljana, Department of Surgical Oncology, Ljubljana, Slovenia Miklós Kásler, National Institute of Oncology, Budapest, Hungary Csaba Polgar, National Institute of Oncology, Budapest, Hungary Dirk Rades, University of Lubeck, Department of Radiation Oncology, Lubeck, Germany , Mirjana Rajer, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Luis Souhami, McGill University, Montreal, Canada Borut Štabuc, University Medical Centre Ljubljana, Department of Gastroenterology, Ljubljana, Slovenia Katarina Šurlan Popovič, University Medical Center Ljubljana, Clinical Institute of Radiology, Ljubljana, Slovenia Justin Teissié, CNRS, IPBS, Toulouse, France Gillian M.Tozer, University of Sheffield, Academic Unit of Surgical Oncology, Royal Hallamshire Hospital, Sheffield, UK Andrea Veronesi, Centro di Riferimento Oncologico- Aviano, Division of Medical Oncology, Aviano, Italy Branko Zakotnik, Institute of Oncology Ljubljana, Department of Medical Oncology, Ljubljana, Slovenia Stojan Plesničar, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Tomaž Benulič, Institute of Oncology Ljubljana, Department of Radiation Oncology, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): A. Editorial office Radiology and Oncology Zaloška cesta 2 P. O. Box 2217 SI-1000 Ljubljana Slovenia Phone: +386 1 5879 369 Phone/Fax: +386 1 5879 434 E-mail: gsersa@onko-i.si Copyright © Radiology and Oncology. All rights reserved. Reader for English Vida Kološa Secretary Mira Klemenčič Zvezdana Vukmirović Design Monika Fink-Serša, Samo Rovan, Ivana Ljubanović Layout Matjaž Lužar Printed by Tiskarna Ozimek, Slovenia Published quarterly in 400 copies Beneficiary name: DRUŠTVO RADIOLOGIJE IN ONKOLOGIJE Zaloška cesta 2 1000 Ljubljana Slovenia Beneficiary bank account number: SI56 02010-0090006751 IBAN: SI56 0201 0009 0006 751 Our bank name: Nova Ljubljanska banka, d.d., Ljubljana, Trg republike 2, 1520 Ljubljana; Slovenia SWIFT: LJBASI2X Subscription fee for institutions EUR 100, individuals EUR 50 The publication of this journal is subsidized by the Slovenian Research Agency. Indexed and abstracted by: • Celdes • Chemical Abstracts Service (CAS) • Chemical Abstracts Service (CAS) - SciFinder • CNKI Scholar (China National Knowledge Infrastructure) • CNPIEC • DOAJ • EBSCO - Biomedical Reference Collection • EBSCO - Cinahl • EBSCO - TOC Premier • EBSCO Discovery Service • Elsevier - EMBASE • Elsevier - SCOPUS • Google Scholar • J-Gate • JournalTOCs • Naviga (Softweco) • Primo Central (ExLibris) • ProQuest - Advanced Technologies Database with Aerospace • ProQuest - Health & Medical Complete This journal is printed on acid- free paper On the web: ISSN 1581-3207 http://www.degruyter.com/view/j/raon http://www.radioloncol.com • ProQuest - Illustrata: Health Sciences • ProQuest - Illustrata: Technology • ProQuest - Medical Library • ProQuest - Nursing & Allied Health Source • ProQuest - Pharma Collection • ProQuest - Public Health • ProQuest - Science Journals • ProQuest - SciTech Journals • ProQuest - Technology Journals • PubMed • PubsHub • ReadCube • SCImago (SJR) • Summon (Serials Solutions/ProQuest) • TDOne (TDNet) • Thomson Reuters - Journal Citation Reports/Science Edition • Thomson Reuters - Science Citation Index Expanded • Ulrich's Periodicals Directory/ulrichsweb • WorldCat (OCLC) Radiol Oncol 2016; 50(2): B. contents contents review 129 Malignant gliomas: old and new systemic treatment approaches Tanja Mesti, Janja Ocvirk 139 Early medical rehabilitation after neurosurgical treatment of malignant brain tumours in Slovenia Natasa Kos, Boris Kos, Mitja Benedicic radiology 145 Screen-detected ductal carcinoma in situ found on stereotactic vacuum-assisted biopsy of suspicious microcalcifications without mass: radiological-histological correlation Bartlomiej Szynglarewicz, Piotr Kasprzak, Przemyslaw Biecek, Agnieszka Halon, Rafal Matkowski nuclear medicine 153 18F-FET and 18F-FCH uptake in human glioblastoma T98G cell lines Marco Giovanni Persico, Federica Eleonora Buroni, Francesca Pasi, Lorenzo Lodola, Carlo Aprile, Rosanna Nano, Marina Hodolic experimental oncology 159 Imaging of human glioblastoma cells and their interactions with mesenchymal stem cells in the zebrafish (Danio rerio) embryonic brain Miloš Vittori, Barbara Breznik, Tajda Gredar, Katja Hrovat, Lilijana Bizjak Mali, Tamara Turnsek Lah 168 Identification of differentially expressed genes associated with the enhancement of X-ray susceptibility by RITA in a hypopharyngeal squamous cell carcinoma cell line (FaDu) Jinwei Luan, Xianglan Li, Rutao Guo, Shanshan Liu, Hongyu Luo, Qingshan You 175 Diffusion tensor MR microscopy of tissues with low diffusional anisotropy Franci Bajd, Carlos Mattea, Siegfried Stapf, Igor Serša clinical oncology 188 The prognostic value of whole blood SOX2, NANOG and OCT4 mRNA expression in advanced small-cell lung cancer Eva Sodja, Matija Rijavec, Ana Koren, Aleksander Sadikov, Peter Korosec, Tanja Cufer Radiol Oncol 2016; 50(2): C. contents 197 Tenckhoff tunneled peritoneal catheter placement in the palliative treatment of malignant ascites: technical results and overall clinical outcome Geert Maleux, Inge Indesteege, Annouschka Laenen, Chris Verslype, Ignace Vergote, Hans Prenen 204 CA19-9 serum levels predict micrometastases in patients with gastric cancer Tomaz Jagric, Stojan Potrc, Katarina Mis, Mojca Plankl, Tomaz Mars 212 Hepatic splenosis mimicking liver metastases in a patient with history of childhood immature teratoma Sara Jereb, Blaz Trotovsek, Breda Skrbinc 218 Treatment of nasopharyngeal carcinoma using simultaneous modulated accelerated radiation therapy via helical tomotherapy: a phase II study Lei Du, XinXin Zhang, LinChun Feng, Jing Chen, Jun Yang, HaiXia Liu, ShouPing Xu, ChuanBin Xie, Lin Ma 226 Bevacizumab plus chemotherapy in elderly patients with previously untreated metastatic colorectal cancer: single center experience Janja Ocvirk, Maja Ebert Moltara, Tanja Mesti, Marko Boc, Martina Rebersek, Neva Volk, Jernej Benedik, Zvezdana Hlebanja radiophysics 232 The dosimetric significance of using 10 MV photons for volumetric modulated arc therapy for post-prostatectomy irradiation of the prostate bed Henry Kleiner, Matthew B. Podgorsak, 238 Effect of photon energy spectrum on dosimetric parameters of brachytherapy sources Mahdi Ghorbani, Mohammad Mehrpouyan, David Davenport, Toktam Ahmadi Moghaddas I slovenian abstracts Radiol Oncol 2016; 50(2): D. 129 review Malignant gliomas: old and new systemic treatment approaches Tanja Mesti1, Janja Ocvirk1,2 1 Department of Medical Oncology, Institute of Oncology Ljubljana, Ljubljana, Slovenia 2 Faculty of Medicine, University of Ljubljana, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 129-138. Received 30 June 2014 Accepted 29 September 2014 Correspondence to: Asisst. Prof. Janja Ocvirk, M.D., Ph.D., Institute of Oncology Ljubljana, Zaloška 2, SI-1000 Ljubljana, Slovenia. Phone: +386 1 5879 220; Fax: +386 1 5879 305; E-mail: jocvirk@onko-i.si Disclosure: No potential conflicts of interest were disclosed. Background. Malignant (high-grade) gliomas are rapidly progressive brain tumours with very high morbidity and mortality. Until recently, treatment options for patients with malignant gliomas were limited and mainly the same for all subtypes of malignant gliomas. The treatment included surgery and radiotherapy. Chemotherapy used as an ad­juvant treatment or at recurrence had a marginal role. Conclusions. Nowadays, the treatment of malignant gliomas requires a multidisciplinary approach. The treatment includes surgery, radiotherapy and chemotherapy. The chosen approach is more complex and individually adjusted. By that, the effect on the survival and quality of life is notable higher. Key words: malignant gliomas; systemic treatment; multidisciplinary; survival; quality of life Introduction Malignant (high-grade) gliomas are rapidly pro­gressive brain tumors comprising of anaplastic oligodendroglioma, anaplastic astrocytoma, mixed anaplastic oligoastrocytoma (all grade III, World Health Organization [WHO]) and glioblastoma (grade IV, WHO).1 The incidence of malignant gliomas is approxi­mately 5/100,000. Malignant gliomas constitute 35–45% of primary brain tumors. Glioblastomas account for approximately 60 to 70% of malignant gliomas, while anaplastic astrocytomas represent 10 to 15%, and anaplastic oligodendrogliomas and anaplastic oligoastrocytomas 10% of malignant gliomas.1-3 The incidence of these tumors has in­creased slightly over past two decades, especially in the elderly. The peak incidence is in the fifth and sixth decade of life. The median age of patients at the time of diagnosis in the case of glioblastoma is 64 years and in the case of anaplastic gliomas 45 years. Malignant gliomas are 40% more frequent in men than in women and twice more frequent in white population than in black one.2,4,5 In Slovenia from 1991 till 2005, a total of 1636 patients (878 males and 758 females) were diag­nosed with brain cancer. Since 2001 till 2005 the microscopical verification was performed in 83% of cases: 82% were gliomas, of which two thirds were glioblastoma, 14% astrocytoma and 10% oligo­dendroglioma. Approximately 60% of the patients were diagnosed at age between 50 to 74 years, and 25% at age between 20 to 49 years.6 The only established environmental risk factor identified for the majority of malignant gliomas is exposure to ionizing radiation.4 There is suggestive evidence with unclear importance of and associa­tion of immunologic factors in the development of malignant gliomas, as patients with atopy have a reduced risk of gliomas7 and patients with glioblas­toma with elevated IgE levels appear to live longer than those with normal levels.8 Also gene polymor­phisms that affect detoxification, DNA repair, and cell cycle regulation have also been implicated in the development of gliomas.4 Few genetic syndromes are associated with the increased risk for malignant gliomas.9 Five percent of patients with malignant gliomas have a family history of gliomas, such as neurofibromatosis 1 and 2, retinoblastoma, the Li-Fraumeni syndrome, the Turcot’s syndrome (the inherited mutations are presented in the Table 1).10 Molecular pathology The malignant gliomas arise from neural progeni­tor cells. Malignant gliomas contain multipotent tumour stem cells that are responsible for populat­ing and repopulating the tumours.11,12 Classical cytogenetic and array – based com­parative genomic hybridization studies of gliomas have identified copy number changes (deletions, amplification, gains) in several regions; deletions TABLE 1. Inherited mutation present in patients with malignant gliomas Neurofibromatosis 1 Neurofibromin 1 (NF1) Neurofibromatosis 2 Neurofibromin 2 (NF2) Tuberous sclerosis Tuberous sclerosis 1 (TSC1) Tuberous sclerosis 2 (TSC2) Retinoblastoma Retinoblastoma 1 (RB1) Li-Fraumeni Tumor suppressor p53 (TP53) syndrome Turcot's syndrome Adenomatous polyposis coli (APC) and multiple DNA mismatch repair genes: hamartoma Recombinant human MutL homolog-1 (hMLH2) MutS homolog 2 (hMSH2) Mismatch repair endonuclease (PMS2) Phosphatase and tensin homolog (PTEN) 17q11 22q12 9q34 16p13 13q14 17p13 5q21 3p21.3 2p22-21 7p22 10q23.3 Differentiated astrocytes or precursors cells p53 mutation (>65 percent) EGFR PDGF-A, PDGFR-. amplificatoni (40 percent) overexpression (60 percent) overexpression (60 percent) MDM2 Low grade astrocytoma amplificatoni (<10 percent) overexpression (50 percent) LOH 19q (50 percent) RB alteration (25 percent) p16 delation (30-40 percent) Anaplastic astrocytoma LOH 10p and 10q LOH 10q PTEN mutation (30 percent) PTEN mutation (5 percent) DCC loss of expression (50 percent) PDGFR-. amplification (<10 percent) RB alternation Secondary glioblastoma Primary glioblastoma de novo FIGURE 1. Development of primary and secondary glioblastoma DCC = deleted in colon cancer gene; LOH = loss of heterozygosity; PDGF = platelet-derived growth factor; PDGFR = platelet-derived growth factor receptor; RB = retinoblastoma gene and loss of heterozygosity in tumours might point to genes involved in tumour initiation or progres­sion (e.g. oncogenes). The chromosomal alterations that are mostly observed in gliomas are presented in Table 2.10 The transition from low grade to anaplastic astrocytoma is associated with inactivation of tumour suppressor genes on chromosomes 9p, 12q and 19q. Loss of chromosome 13q, which in­cludes the retinoblastoma (RB) gene focus, occurs in approximately 30% of higher-grade astrocytic tumours. Two-thirds of malignant astrocytomas and glioblastomas have homozygous deletions of the region of chromosome 9p that includes the cyclin-dependent kinase inhibitor 2A (CDKN2A) and CDKN2B genes. In general, RB, CDKN2A and cyclin- dependent kinase (CDK)4 gene altera­tions are mutually exclusive in glioblastomas.13 Malignant progression to glioblastoma is also as­sociated with inactivation of the phosphatase and tensin homolog (PTEN) tumour suppressor gene on chromosome 10 and amplification of the epi­dermal growth factor receptor (EGFR) gene.14 The loss of chromosome 10 occurs in 60% to 85% of glioblastomas, with approximately 25% of cases having PTEN mutation.15 In approximately 40% of glioblastomas the EGFR gene is amplified, result­ing in overexpression of EGFR.16 Glioblastomas can be classified as primary or de novo and secondary or progressive. Primary glio­blastomas comprises the majority of cases (60%), develop in older patients (> 50y), without prior clin­ical history of less malignant tumours, presenting after the short medical history (less than 6 months). Secondary or progressive glioblastomas (40%) are common among younger people (< 45y) and arise through the progression from lower-grade astrocy­tomas (WHO grade II) or anaplastic astrocytomas (WHO grade III), with varying time for the pro­gression, between less than 1 year to more than 10 years. Primary and secondary glioblastomas obvi­ously constitute distinct disease entities that evolve through different genetic pathways. CDKN2A de­letions, PTEN alterations and EGFR amplification are more prevalent among de novo glioblastomas and less frequently, mouse double minute 2 ho­molog (MDM2) amplification, whereas p53 mu­tations develop as earliest detectable alteration in secondary glioblastomas (Figure 1).17 Prognostic factors Age, tumour grade (anaplastic gliomas versus glio­blastoma) and performance status are three most 131 TABLE 2. The chromosomal alterations, mostly observed in gliomas 1p36.31-pter Gains and deletions Not known 1p36.22-p36.31 Gains and deletions Not known 1p34.2-p36.1 Gains and deletions Not known 1q32 Gains Receptor interacting protein kinase 5 (RIPK5), mouse double minute 4 (MDM4), phosphatidylinositol-4-phosphate 3-kinase, catalytic subunit type 2 beta (PIK3C2B) and others 4q Deletions NIMA-related kinase 1 (NEK1), NIMA 7p11.2-p12 Amplifications or gains Epidermal growth factor receptor (EGFR) 9p21-p24 Deletions Cyclin-dependent kinase inhibitor 2A (CDKN2) 10q23 Deletions Phosphatase and tensin homolog (PTEN) 10q25-q26 Deletions O-6-methylguanine-DNA methyltransferase (MGMT) 11p Deletions Between cyclin-dependent kinase inhibitor 1C (CDKN1C) and related RAS viral (r-ras) oncogene homolog 2 (RRAS2) 12q13.3-q15 Amplifications Mouse double minute 2 homolog (MDM2), cyclin-dependent kinase 4 (CDK4) and others 13p11-p13 and 13q14-q34 Loss Retinoblastoma 1 (RB1) 19q13 Loss Glioma tumor suppressor candidate region gene 1 (GLTSCR1), GLTSCR2, ligase I, DNA, ATP-dependent (LIG1), cytohesin 2 (CYTH2) and many others 22q11.21-q12.2 Loss 28 genes, including integrase interactor 1 (INI1) 22q13.1-q13.3 Loss Not known important prognostic factors affecting response to the treatment, along with extend of initial surgical resection.5,18,19 Lamborn et al. showed the aforemen­tioned by study of 832 patients with glioblastoma in which the outcome was analysed by the recur­sive partitioning analysis.20 Also for patients with newly diagnosed glioblas­toma, nomograms that incorporate patient age, ex­tent of resection, use of postoperative (adjuvant) temozolomide, mental status and corticosteroid use as a baseline for prognostic factors, have been developed for estimation of the median survival and two year survival probability, as a helpful tool in decision making for individual patients.21 Nomograms have been developed on the bases of Stupp et al., temozolomide adjuvant trial from Prognostic and predictive markers Oligodendrogliomas with 1p/19q deletions have been recognized as distinct pathologic entities with particular sensitivity to RT and chemothera­py (ChT). In the retrospective analysis, the patients with tumours’ epigenetic silencing of the methyl-guanine methyl transferase (MGMT) gene promot­er by methylation benefited from temozolomide. The tumours were unable to repair ChT induced DNA damage.23 IDH1 (NADP+-dependent isocitrate dehydro­genases) mutation occurs in the vast majority of WHO grade II or III gliomas and secondary glio­blastomas.24 The p.Arg132His mutation (substitu­tion of arginine with histidine) of isocitrate dehy­drogenase 1 (IDH1R132H) is not only a frequent al­teration (> 70%) but also a major prognostic marker in gliomas.25 Patients with IDH1 mutation have a better treatment outcome and a better survival.26 Diagnosis Clinical manifestations Clinical manifestations of malignant gliomas de­pend on the localization and size of the tumour. The variety of symptoms may be present, such as headaches and seizures (50.60%), focal neurologic deficits, confusion, memory loss and personality changes (20%).27 The classic headache suggestive of increased in­tracranial pressure is most severe in the morning and may be associated with nausea and vomitting.28 Rarely meningeal dissemination may be the first presentation of malignant gliomas as back pain TABLE 3. Symptoms at presentation of glioblastoma Headache Nausea/vomiting Cognition changes Personality changes Gait imbalance Urinary incontinence Hemiparesis Aphasia Hemineglect Visual field defect Seizures with or without radicular symptoms, mental status changes, cranial nerve palsies, and myelopathy or cauda equina syndrome (Table 3).29,30 Imaging Diagnosis and staging are made by imaging of the brain and tumour hystopathologic verifica­tion. For imaging the magnetic resonance (MRI) is preferred, but computed tomography may also be used. Additional biopsy or tumour resection fol­lows afterwards. Imaging studies show heterogeneously enhanc­ing mass with surrounding oedema. Glioblastomas frequently have central areas of necrosis and more extensive peritumoral oedema than in anaplastic gliomas.31 Tissue diagnosis is essential, it can be attended either at the time of surgical resection or by sepa­rate procedure named frameless stereotactic biop­sy. In the case of frameless stereotactic biopsy, the neurosurgeon is aware of the three dimensional positions of surgical instruments inside the intrac­ranial space during the biopsy, because it is MRI or CT guided.32 The procedure related mortality is 1–2%.33 Positron emission tomography (PET)34 and mag­netic resonance spectroscopy (MRS) can be used to identify metabolically active areas of different tu­mours, and by that increasing the accuracy of ste­reotactic brain biopsy. PET can be integrated with the use of 18F-labeled fluorodeoxyglucose (FDG­PET) or L-[methyl-(11) C]-methionine (MET-PET) increasing the diagnostic sensitivity and specifici­ty. The both image procedures MET-PET and FDG­PET correspond with each other.35 Systemic treatment for malignant gliomas Postoperative (adjuvant) therapy Glioblastoma Because of their infiltrative nature, malignant glio­mas cannot be completely eliminated with surgery. The standard treatment after surgery today for glio­blastoma is concomitant RT-ChT with temozolomide (RT of 60 Gy and temozolomide 75 mg/m2/day for 6 weeks), followed by the adjuvant temozolomide therapy (150-200 mg/m2/day for 5 days every 28 days for 6 cycles). As reported by Stupp et al.22, this RT-ChT) combination has an acceptable side effect profile and as compared with RT alone (60 Gy for 6 weeks), increased the median survival (14.6 months vs. 12.1 months, p < 0.001). The survival rate among the patients treated with RT/CTh was significantly higher than the rate among the patients that re­ceived RT alone at two and five years, respectively (26.5% vs. 10.4% and 10% vs. 2%). MGMT promoter methylation was a major prog­nostic factor for the improved survival and was predictive of benefit from the therapy. For those with MGMT methylation, the two years survival rates were 49% and 24% with combination therapy and RT alone respectively, while for those without MGMT methylation, the two year survival rates were 15% and 2% respectively. The 5-year overall survival analysis of the European Organisation for Research and Treatment of Cancer (EORTC) and National Cancer Institute of Canada (NCIC) trial has shown benefit for pa­tients treated with RT and temozolomide compared with only irradiated patients (9.8% vs. 1.9%), the median survival after the progression remains only 6.2 months, regardless of the initial treatment.36 Adjuvant ChT with procarbazine, lomustine (CCNU) and vincristine (PCV regimen) has failed to improve the survival in individual prospective randomized studies, both in grade IV and in grade III tumours. One large meta-analysis has showed that nitrosourea based CTh marginally improves the survival. Namely, individual patient data from 3004 patients enrolled in 12 randomized controlled trials comparing RT alone or with CTh, were in­cluded, CTh was associated with a 15% decrease in the risk of death, which translated to a 6% ab­solute increase in one year survival (from 40% to 46%) and a two month improvement in the median survival.37 There are no randomized trials that have com­pared temozolomide with a nitrosourea-based 133 TABLE 4. Summary of current treatments for malignant gliomas* (Adapted from ref.28) Newly diagnosed tumours Glioblastoma (WHO grade IV) Maximal surgical resection, plus radiotherapy, plus concomitant and adjuvant TMZ ** Maximal surgical resection, with the following options after surgery (no accepted standard Anaplastic astrocytoma (WHO grade III) treatment): radiotherapy, plus concomitant and adjuvant TMZ or adjuvant TMZ alone** Maximal surgical resection, with the following options after surgery (no accepted standard Anaplastic oligodendroglioma and treatment): radiotherapy alone, TMZ or PCV with or without radiotherapy afterward, anaplastic oligoastrocytoma (WHO grade III) radiotherapy plus concomitant and adjuvant TMZ, or radiotherapy plus adjuvant TMZ**+ Reoperation in selected patients, conventional chemotherapy (e.g., lomustine, carmustine, PCV, Recurrent tumours carboplatin, irinotecan, etoposide), bevacizumab plus irinotecan, experimental therapies + * Additional data are from Sathornsumette et al.47, Furnari et al.48, Chi and Wen49 and Sathornsumetee et al.50 ; ** Radiotherapy is administered at a dose of 60 Gy given in 30 fractions over a period of 6 weeks. ; Adjuvant TMZ = adjuvant temozolomide, beginning 4 weeks after radiotherapy, 150 mg/m2/day on days 1 to 5 of the first 28-day cycle, followed by 200 mg/m2/day on days 1 to 5 of each subsequent 28-day cycle, if the first cycle was well tolerated; Concomitant TMZ = concomitant temozolomide, 75 mg/m2/ day for 42 days with radiotherapy; PCV = lomustine (CCNU), 110 mg/m2, on day 1; procarbazine, 60 mg/m2 on days 8 to 21; vincristine, 1,5 mg/m2 (maximum dose, 2 mg), on days 8 and 29; WHO = World Health Organization combination regimen when given concurrently with RT followed by the adjuvant therapy. Another chemotherapeutic approach involves the implantation of biodegradable polymers con­taining carmustine (Gliadel Wafers, MGI Pharma) into the tumour bed after the resection of the tu­mour. The aim of the treatment with these poly­mers, which release carmustine gradually over the course of several weeks, is to kill residual tumour cells. In a randomized, placebo-controlled trial that investigated the use of these polymers in patients with newly diagnosed malignant gliomas, the me­dian survival increased from 11.6 months to 13.9 months (p = 0.03).38 This survival advantage was maintained at 2 and 3 years.39 The newest phase III study data, in patients with newly diagnosed patients with glioblastoma, are coming from Radiation Therapy Oncology Group (RTOG) 0825 and Avastin in Glioblastoma (AVAGLIO) studies. In RTOG 0825 study, 637 newly diagnosed patients were randomly assigned to receive either standard ChT-RT (with temozo­lomide plus bevacizumab (10 mg/kg intravenous [IV], q 2 weeks), or standard ChT-RT plus placebo). The progression-free survival was significantly im­proved in the bevacizumab arm: 10.7 months vs. 7.3 months for placebo. However, the overall survival was slightly (although not significantly) worse in the bevacizumab arm: 15.7 months vs. 16.1 months for placebo. In addition, patients in the bevacizum­ab arm had a greater symptom burden and worse neurocognitive functioning, and they scored worse on several measures of health-related quality of life (QOL) than did patients who received only a stand­ard therapy.40 The AVAGLIO trial, which had a study design very similar to that of RTOG 0825 and which in­volved 921 patients, also showed an improvement in progression-free survival (10.6 months in the bevacizumab arm vs. 6.2 months in the placebo arm) but virtually identical overall survival (16.8 months vs. 16.7 months, respectively). However, the QOL outcome in the bevacizumab arm was more favourable than in RTOG 0850 and time to the initiation of the corticosteroid treatment to manage adverse effects was also significantly longer in the patients who received bevacizumab (a median of 12.3 months vs. 3.7 months for placebo).41 Anaplastic astrocytoma The standard therapy after surgery for anaplastic astrocytoma is still RT up to 60 Gy after the surgery. Currently, there are no findings from controlled trials that support the use of concurrent temozo­lomide in patients with anaplastic astrocytomas.42 Anaplastic oligodendrogliomas and anaplastic oligoastrocytomas Anaplastic oligodendrogliomas and anaplastic oli­goastrocytomas are generally more responsive to therapy than are pure astrocytic tumours.43 Nearly 90% of patients with anaplastic oligodendroglio­mas and 20% patients with anaplastic oligoas­trocytomas has a co-deletion of chromosomes 1p and 19q, mediated by an unbalanced translocation of 19p to 1q.44 Tumours in patients with the LOH 1p/19q co-deletion are particularly sensitive to CTh with PCV with response rates of up to 100%, as compared with response rates of 23 to 31% among patients without the deletion LOH of 1p/19q. Two large phase III studies of PCV ChT with RT, as compared with RT alone, in patients with newly diagnosed anaplastic oligodendrogliomas or ana­plastic oligoastrocytomas, have been reported. In both studies, the addition of ChT to RT increased the time to tumour progression by 10 to 12 months, but, did not improve the overall survival (median, 3.4 and 4.9 years).45,46 No difference in efficacy was apparent between PCV and temozolomide CTh43, however, studies directly comparing the two regi­mens have not been performed (Table 4). Pseudo progression In patients with malignant gliomas, treated with temozolomide and RT, have been described with sub-acute treatment-related reactions with or with­out clinical deterioration, showing oedema and sometimes contrast enhancement on MRI, sug­gestive of tumour progression.51-53 The occurrence of pseudo progression is mostly within the first 2 months after temozolomide ChT-RT. In a prospective phase III trials with RT only, pseudo progression occurred in three of 32 (9%) pa­tients.54 More recent study on 85 patients with ma­lignant gliomas treated with temozolomide ChT-RT, pseudo progression occurred in 18 (21%) patients.55 In one third of patients treated with temozolomide ChT-RT, the increase in radiological abnormalities was accompanied by new focal signs, but in most patients the increase in radiological abnormalities was clinically asymptomatic.55 In the study involv­ing 103 patients, pseudo progression was noted in 32 patients (31%), and was clinically symptomatic in 11 (34%) of these patients. Patients with MGMT have more frequent pseudo progression and it was connected with better overall survival.56 Most likely, pseudo progression is induced by a pronounced local tissue reaction with an inflam­matory component, oedema, and abnormal vessel permeability causing new or increased contrast en­hancement on neuroimaging. In less severe cases, this event can subside without the further treat­ment, but in more severe cases it can result, over time, in true treatment-related necrosis. The possibilities of a good functional outcome in patients with malignant gliomas could be increased with good early medical rehabilitation treatment.57 Treating the recurrent malignant gliomas For glioblastoma, median time to progression af­ter the treatment with RT and temozolomide is 6.9 months.36 In case of symptomatic disease from mass effect, reoperation may be indicated (Table 4), with limited prolongation of survival afterwards.58 The treatment of recurrent malignant gliomas with RT is controversial. Some data have suggest­ed that fractionated stereotactic reirradiation (SRT) and stereotactic radiosurgery (SRS) may be benefi­cial.59 Observational series of patients with recur­rent malignant gliomas, treated with SRT showed the median survival of 12 months for patients with grade III tumours and eight months for those with grade IV lesions.60 The one-year survival rates were 65% and 23 % for patients with grade III and IV le­sions, respectively. Kong DS et al. in patients with recurrent gliomas treated with SRS has achieved progression free survival for patients with grade III and grade IV of 8.6 and 4.6 months, respective­ly.61 All patients were treated with SRS treatments delivered by gamma knife, except for 5 patients treated by linear accelerator. The conventional ChT is more effective for anaplastic gliomas than for glioblastomas. In gen­eral, the conventional ChT has modest value for recurrent malignant gliomas. There is no estab­lished ChT regimen available and patients are best treated within investigational clinical protocols. Temozolomide was evaluated in a phase II study in patients with recurrent anaplastic gliomas who had previously been treated with nitrosoureas.62 The response rate was 35%, and the 6-month rate of progression-free survival was 46%, comparing favourably with the 31% rate of progression-free survival at 6 months for therapies that were re­ported to be ineffective.63 In patients with recur­rent glioblastomas, temozolomide has only limited activity, with response rate of 5.4% and 6-month rate of progression-free survival of 21%.64 Different temozolomide doses and administration regimens have been developed. With the aim of depleting MGMT, Brock et al.65 conducted a phase I trial of continuous temozolomide administration, demon­strating that a dose of 75 mg/m2 daily up to 49 days is safe. Continuous dose-dense temozolomide ad­ministration at a dose of 100 mg/m2 for 3 weeks out of 4 or 150 mg/m2 1 week out of 2 will double the dose intensity and deplete peripheral blood mono-nuclear cells of MGMT.66,67 Continuous temozolo­mide administration is associated with profound lymphocytopenia and an increased risk for oppor­tunistic infections.68,69 Other chemotherapeutic agents that are used for recurrent gliomas include nitrosoureas, car­boplatin, procarbazine, irinotecan, and etoposide. Nitrosoureas (carmustine, fotemustine) either as single agents or in combination regimens as pro­carbazine, lomustine and vincristine (PCV) have shown activity in phase II studies in previously treated patients. Brandes et al. conducted a phase II study on 40 patients with recurrent glioblastoma 135 following surgery and standard RT, treated with carmustine as monotherapy. Median time to pro­gression was 13.3 weeks and progression-free sur­vival at 6 months was 17.5%.70 As combination regiment PCV, Schmidt F et al., has applied to 86 patients with recurrent glioblas­toma. There were three partial responses, but no complete responses. Median progression-free sur­vival was 17.1 weeks and progression-free survival at 6 months was 38.4%.71 Bevacizumab is a monoclonal antibody, which binds to vascular endothelial growth factor (VEGF), the key driver of neovascularization, and thereby inhibits the binding of VEGF to its recep­tors, VEGFR-1 and VEGFR-2, on the surface of en­dothelial cells. It demonstrated significant clinical activity in phase II studies using bevacizumab as a single agent or in combination with ChT agents such as irinotecan for patients with grade 3 and grade 4 malignant gliomas (higher objective re­sponse, progression-free survival and overall survival) in recurrent glioblastomas72-74 and has been approved by Food and Drug Administration (FDA) for the secondary treatment of glioblastoma in USA75, but it is not approved yet by European Medicines Agency (EMA).76 The most extensive experience with bevacizum­ab comes from a noncomparative phase II trial, in which 167 patients with recurrent glioblastomas, priory treated with ChT with temozolomide, were randomly assigned to bevacizumab, either as a sin­gle agent or at the same dose in conjunction with irinotecan.73 Treatment cycles were repeated every two weeks. The objective response rates with beva­cizumab alone or in combination with irinotecan were 28% and 38%, respectively, and the six-month progression-free survival rates and overall survival were 43% and 50 %, and 9.2 and 8.7 months, re­spectively. An update of the results was presented at the 2010 American Society of Clinical Oncology (ASCO) meeting.74 Overall safety and efficacy were similar to that previously presented; the 12 and 24-month survival rates were 38% and 16% to 17% on both treatment arms, which appear to be better than historical control series. According to our experience, at Institute of Oncology Ljubljana, we treated 19 patients with recurrent malignant gliomas with bevacizumab and irinotecan, from August 2008 to November 2011. The objective response rates were 47.4 % and 10.5% after 3 and 6 months respectively. The six-month time to progression interval rate and over­all survival were 52.6% and 68.4% and 6.8 and 7.7 months, respectively (Figure 1).77 Bevacizumab alone or in combination with ChT has not been demonstrated to prolong the overall survival. Pivotal studies to determine the impact of this agent on overall survival are ongoing. Treating the elderly According to the Central Brain Tumor Registry of United States of America (CBTRUS), in one series of over 14,000 cases, 44% of cases were patients aged 65 years or more.78 Older age and poor perfor­mance status are associated with shorter survival. RT among patients older than 70 years has a modest benefit in the median survival (29.1 weeks) as compared with supportive care (16.9 weeks).79 Older patients tolerate therapy less well than younger patients, so the treatment regimen should be adjusted. RT applied as abbreviated course (40 Gy in 15 fractions over a period of 3 weeks) or temozolomide as monotherapy has similar out­comes as conventional RT regimens.80,81 Two contemporary randomized trials conduct­ed exclusively in older patients have new data about the optimal treatment approach. Both trials, Methusalem trial (NOA-08)78 and Nordic Elderly Trial82 have compared initial ChT as monotherapy with RT alone. In the Methusalem Trial the median age was 72 years.78 Patients treated with RT has a better survival, the median survival was 293 vs. 245 days, one year survival was 38% vs. 31%, the toxici­ty was more severe in patients treated with CTh. In Nordic Elderly Trial the median age was 70 years. Patients were treated with RT 60 Gy (6 weeks), 34 Gy (6 weeks) and temozolomide as monothera­ TABLE 5. Selected investigational therapies for malignant gliomas* (Adapted from ref. 28) Convection enhanced surgical Cintredekin besudotox delivery of pharmacologic agent Drugs to overcome resistance to TMZ Dose dense TMZ O6-benzylguanine MGMT inhibitors BSI-201, ABT-888 PARP inhibitors RTA 744, ANG 1005 New chemotherapies Antiangiogenic therapies Anti-avb5 integrins Cilengitide Anti-hepatocyte growth factor AMG-102 Anti-VEGF Bevacizumab, aflibercept (VEGF-trap) Anti-VEGFR Cediranib, pazopanib, sorafenib, sunitinib, vandetinib, vatalanib, XLI 84, CT-322 Other agents Thalidomide Targeted molecular therapies Akt Perifosine EGFR inhibitors Erlotinib, gefitinib, lapatinib, BIBW2992, nimotuzumab, cetuximab FTI inhibitors Tipifarnib, lonafanib HDAC inhibitors Vorinostat, depsipeptide, LBH589 HSP90 inhibitors ATI3387 Met XLI84 mTOR inhibitors Everolimus, sirolimus, temsirolimus, deforolimus PI3K inhibitors BEZ235, XL765 PKCb Enzastaurin PDGFR inhibitors Dasatinib, imatinib, tandutinib Proteasome Bortezomib Raf Sorafenib Src Dasatinib TGF-b API2009 Combination therapies Erlotinib plus temsirolimus, gefitinib plus everolimus, gefitinib plus sirolimus, saorafenib plus temsirolimus, erlotinib, or tipifarnib, pazopanib plus lapatinib Immunotherapies Dendritic cell and EGFRvIII peptide DCVax, CDX-110 vaccines Monoclonal antibodies 131I-anti-tenascin antibody Gene therapy Other therapies 131I-TM-601 * Additional data are from Sathorsumetee et al.47, Furnari et al.48, Chi and Wen49, Sathornsumetee et al.50 ; EGFR = epidermal growth factor; FTI = farnesyltransferase; HDAC = histone deacetylase; HSP90 = heat-shock protein 90; MGMT = O6-methylguanine-DNA methyltransferase; mTOR = mammalian target of rapamycin; PARP = poly (ADP-ribose) polymerase; PDGFR = platelet-derived growth factor receptor; PI3K = phosphatidylinositol 3-kinase; PKCb = protein kinase Cb; TGF = transforming growth factor; TMZ = temozolomide; VEGFR = vascular ednosthelial growth factor receptor; WHO = World Health Organization py. In this trial patients treated with CTh had a bet­ter survival, with the overall survival of 6, 7.5 and 8.3 months, respectively. It seems that there might be benefit from systemic treatment over RT in pa­tients with MGMT methylated tumours. Experimental approaches Increased understanding of the molecular path­ways involved in signal transduction, angiogenesis and cell growth has led to the development of a number of targeted agents, which are now under active evaluation, alone and in various combina­tions for patients with malignant gliomas and other tumours. Other investigational therapies for malig­nant gliomas include chemotherapeutic agents that cross the blood-tumour barrier more effectively, gene therapy, peptide and dendritic-cell vaccines, radiolabeled monoclonal antibodies against the ex­tracellular matrix protein tenascin, synthetic chlo­rotoxins (131I-TM-601), and infusion of radiolabeled drugs and targeted toxins into the tumour and sur­rounding brain by means of convection-enhanced delivery. Promising investigational therapies are selected in Table 5.28 Conclusions Malignant gliomas remains difficult to treat, and despite the efforts to improve the treatment out­come, the survival of patients with malignant glio­mas is poor, with median survival of slightly above one year. After revolutionary change in the postoperative setting with RT-ChT with Temozolomide has been achieved, mostly negative trials follow. AVAGLIO and RTOG 0825 trials were negative. Even though the AVAGLIO trial kind of suggests progression-free survival and QOL improvement, these are not clear cut results and upon review the actual pro-gression-free survival benefit was smaller, while QOL results are completely contradictory. In the recurrent malignant glioma setting, still nothing significant has been achieved. The optimal management requires a multidis­ciplinary approach and knowledge of potential complications from both the disease and its treat­ment. In the future, with the better understanding of the molecular pathogenesis of malignant glio­mas, it may be possible to select the most appropri­ate therapies on the basis of the patient’s tumour genotype and in that way more effective therapies can be developed for malignant gliomas. Most of 137 all, further targeted therapy approaches should be biomarker driven. References 1. WHO Classification of tumours of the central nervous system. Louis DN, Ohgaki H, Wiestler OD, Cavenee WK, editors. Lyon: IARC Press; 2007. 2. CBTRUS, Central Brain Tumor Registry of the United States. 2007–2008. Primary brain tumors in the United States. Statistical report. 2000– 2004 years of data collected. Available from: http://www.cbtrus.org/ reports/2007-2008/2007report.pdf. Accessed on 10 November 2013. 3. Kase M, Minajeva A, Niinepuu K, Kase S, Vardja M, Asser T, et al. Impact of CD133 positive stem cell proportion on survival in patients with glioblas­toma multiforme. Radiol Oncol 2013; 47: 405-10. 4. Fisher JL, Schwartzbaum JA, Wrensch M, Wiemels JL. Epidemiology of brain tumors. Neurol Clin 2007; 25: 867-90. 5. Smrdel U, Kovac V, Popovic M, Zwitter M. Glioblastoma patients in Slovenia from 1997 to 2008. Radiol Oncol 2014; 48: 72-9. 6. Zakelj MP, Zadnik V, Zagar T, Zakotnik B. Survival of cancer patients, diag­nosed in 1991-2005 in Slovenia. Ljubljana: Institute of Oncology Ljubljana, Epidemiology and Cancer Registry, Cancer Registry of Republic of Slovenia; 2009. p. 229. 7. Linos E, Raine T, Alonso A, Michaud D. Atopy and risk of brain tumours: a metaanalysis. J Natl Cancer Inst 2007; 99: 1544-50. 8. Wrensch M, Wiencke JK, Wiemels J, Miike R, Patoka J, Moghadassi M, et al. Serum IgE, tumour epidermal growth factor receptor expression and inherited polymorphisms associated with gliomas survival. Cancer Res 2006; 66: 4531-41. 9. Farell CJ, Plotkin SR. Genetic causes of brain tumors: neurofibromatosis, tuberous sclerosis, von Hippel-Lindau and other syndromes. Neurol Clin 2007; 25: 925-46. 10. Schwartzbaum JA, Fisher JL, Kenneth DA, Wrensch M. Epidemiology and molecular pathology of gliomas. Nature 2006; 2: 494-503. 11. Galli R, Binda E, Orfanelli U, Cipelletti B, Gritti A, De Vitis S, et al. Isolation and characterization of tumorigenic, stem-like neural precursors from human glioblastoma. Cancer Res 2004; 64: 7011-21. 12. Singh SK, Hawkins C, Clarke ID, Squire JA, Bayani J, Hide T, et al. Identification of human brain tumor initiating cells. 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Fiegler W, Langer M, Scheer M, Kazner E. [Reversible computed tomograph­ic changes following brain tumour irradiation induced by the “early-delayed reaction” after radiation]. [German]. Radiologe 1986; 26: 206-9. 52. Watne K, Hager B, Heier M, Hirschberg H. Reversible oedema and necrosis after irradiation of the brain. Diagnostic procedures and clinical manifesta­tions. Acta Oncol 1990; 29: 891-5. 53. Griebel M, Friedman HS, Halperin EC, Wiener MD, Marks L, Oakes WJ, et al. Reversible neurotoxicity following hyperfractionated radiation therapy of brain stem gliomas. Med Pediatr Oncol 1991; 19: 182-6. 54. de Wit MC, de Bruin HG, Eijkenboom W, Sillevis Smitt PA, van den Bent MJ. Immediate post-radiotherapy changes in malignant gliomas can mimic tumour progression. Neurology 2004; 63: 535-7. 55. Taal W, Brandsma D, de Bruin HG, Bromberg JE, Swaak-Kragten AT, Smitt PA, et al. The incidence of pseudoprogression in a cohort of malignant gliomas patients treated with chemo-radiation with temozolomide. [Abstract]. Proc Am Soc Clin Oncol 2007; 25: Abstract No. 2009. 56. Brandes AA, Franceschi E, Tosoni A, Blatt V, Pession A, Tallini G, et al. MGMT promoter methylation status can predict the incidence and outcome of pseudoprogression after concomitant radiochemotherapy in newly diag­nosed glioblastoma patients. J Clin Oncol 2008; 26: 2192-7. 57. Kos N, Kos B, Benedicic M. Early medical rehabilitation after neurosurgical treatment of malignant brain tumours in Slovenia. Radiol Oncol 2015; 49: in press. 58. Keles GE, Lamborn KR, Chang SM, Prados MD, Berger MS. Volume of re­sidual disease as a predictor of outcome in adult patients with recurrent su­pratentorial glioblastomas multiforme who are undergoing chemotherapy. J Neurosurg 2004; 100: 41-6. 59. Tsao MN, Mehta MP, Whelan TJ, Morris DE, Hayman JA, Flickinger JC, et al. 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Selective CD4+ lymphopenia in melanoma patients treated with temozolomide: a toxicity with therapeutic implications. J Clin Oncol 2004; 22: 610-6. 69. Wick W, Weller M. How lymphotoxic is dose-intensified temozolomide? The glioblastoma experience. J Clin Oncol 2005; 23: 4235-6; author reply 4236. 70. Brandes AA, Tosoni A, Amista P, Nicolardi L, Grosso D, Berti F, et al. How ef­fective is BCNU in recurrent glioblastoma in the modern era? A phase II trial. Neurology 2004; 63: 1281-4. 71. Schmidt F, Fischer J, Herrlinger U, Dietz K, Dichgans J, Weller M. PCV chemo­therapy for recurrent glioblastoma. Neurology 2006; 66: 587-9. 72. Kreisl TN, Kim L, Moore K, Duic P, Royce C, Stroud I, et al. Phase II trial of single-agent bevacizumab followed by bevacizumab plus irinotecan at tumor progression in recurrent glioblastoma. J Clin Oncol 2009; 27: 740-5. 73. Friedman HS, Prados MD, Wen PY, Mikkelsen T, Schiff D, Abrey LE, et al. Bevacizumab alone and in combination with irinotecan in recurrent glio­blastoma. J Clin Oncol 2009; 27: 4733-40. 74. Cloughesy T, Vredenburgh JJ, Day B, Das A, Friedman HS. Updated safety and survival of patients with relapsed glioblastoma treated with beva­cizumab in the BRAIN study. [Abstract]. J Clin Oncol 2010; 28(15 Suppl): Abstract No. 3085. 75. NCCN clinical practical guidelines in oncology. Central nervous system can­cer. Version 2.2013. Available from: http://www.nccn.org/professionals/ physician_gls/f_guidelines.asp#site. Accessed on 7 August 2012. 76. Stupp R, Tonn JC, Brada M, Pentheroudakis G. High grade malignant glioma: ESMO clinical practice guidelines for diagnosis, treatment and follow-up. Ann Oncol 2010; 21(Suppl 5): v190-3. 77. Mesti T, Ebert Moltara M, Boc M, Reberšek M, Ocvirk J. Bevacizumab and irinotecan in recurrent malignant glioma, a single institution experience. Radiol Oncol 2014. Ahead of print. doi:10.2478/raon-2014-0021 78. Wick W, Engel C, Combs SE, Nikkhah G, Steinbach J, Kortmann R, et al. NOA­08 randomized phase III trial of 1 week on/1 week off temozolomide versus involved-field radiotherapy in elderly (older than age 65) patients with newly diagnosed anaplastic astrocytoma or glioblastoma (Methusalem). [Abstract]. J Clin Oncol 2010; 28: 949s. Abstract No. LBA2001. 79. Keime-Guibert F, Chinot O, Taillandier L, Cartalat-Carel S, Frenay M, Kantor G, et al. Radiotherapy for glioblastoma in the elderly. N Engl J Med 2007; 356: 1527-35. 80. Roa W, Brasher PM, Bauman G, Anthes M, Bruera E, Chan A, et al. Abbreviated course of radiation therapy in older patients with glioblastoma multiforme: a prospective randomized clinical trial. J Clin Oncol 2004; 22: 1583-8. 81. Glantz M, Chamberlain M, Liu Q , Litofsky NS, Recht LD. Temozolomide as an alternative to irradiation for elderly patients with newly diagnosed malig­nant gliomas. Cancer 2003; 97: 2262-6. 82. Malmstrom A, Gronberg BH, Stupp R, Marosi C, Frappaz D, Schultz HP, et al. Glioblastoma (GBM) in elderly patients: a randomized phase III trial comparing survival in patients treated with 6-week radiotherapy (RT) ver­sus hypofractionated RT over 2 weeks versus temozolomide single agent chemotherapy (TMZ) for glioblastoma (GBM) in the elderly. [Abstract]. J Clin Oncol 2010; 28(18 Suppl): 949s. Abstract No. LBA2002 139 review Early medical rehabilitation after neurosurgical treatment of malignant brain tumours in Slovenia Natasa Kos1, Boris Kos2, Mitja Benedicic3 1 Medical Rehabilitation Unit, University Medical Centre, Ljubljana, Slovenia 2 Zdravstveni dom dr. Julija Polca Kamnik, Slovenia 3 Department of Neurosurgery, University Medical Centre, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 139-144. Received 23 September 2014 Accepted 3 December 2014 Correspondence to: Mitja Benedičič, M.D., Ph.D., Department of Neurosurgery, University Medical Centre Ljubljana, Zaloška 2, SI-1000 Ljubljana, Slovenia. E-mail: mitja.benedicic@kclj.si Disclosure: No potential conflicts of interest were disclosed. Background. The number of patients with malignant brain tumours is on the rise, but due to the novel treatment methods the survival rates are higher. Despite increased survival the consequences of tumour properties and treat­ment can have a significant negative effect on the patients’ quality of life. Providing timely and appropriate rehabili­tation interventions is an important aspect of patient treatment and should be started immediately after surgery. The most important goal of rehabilitation is to prevent complications that could have a negative effect on the patients’ ability to function. Conclusions. By using individually tailored early rehabilitation it is often possible to achieve the patients’ independ­ence in mobility as well as in performing daily tasks before leaving the hospital. A more precise evaluation of the patients’ functional state after completing additional oncologic therapy should be performed to stratify the patients who should be directed to complex rehabilitation treatment. The chances of a good functional outcome in patients with malignant brain tumours could be increased with good early medical rehabilitation treatment. Key words: malignant brain tumour; surgery; early rehabilitation Introduction Malignant brain tumours have a very high likeli­hood of producing disabling effects on a patient’s life. The indirect effects of chemotherapy and radi­ation therapy add to the functional deficits which are usually caused by the tumour itself (mass ef­fect). Neurological deficits are related to the area of the brain that the tumour invades. The most common neurological complications of primary brain tumours are cognitive deficits (80%), motor deficits (78%), visual-perceptual deficits (53%), sensory loss (38%), bowel/bladder impairment (37%), cranial nerve palsy (29%), dysarthria (27%), dysphagia (26%), aphasia (24%) and ataxia (20%).1 The observed preoperative and postoperative neu­rological deficits have an important impact on pa­tients’ daily life functions and result in diminished ability to perform usual family and social roles. Furthermore, most of the patients experience pro­gressive neurological decline as their disease pro­gress.2 Brain tumours occur over the life span with higher incidence in advanced age.3 The survival rates have increased due to early diagnostics and up-to-date multidisciplinary treatment involving neurologists, neuroradiologists, neurosurgeons, oncologists and the medical rehabilitation spe­cialists.4,5 However, besides prolonged survival6, the contemporary approach is the maintained or improved quality of life, which can be much con­tributed to by the rehabilitation processes, which needs to be adjusted to the individual’s abilities. The purpose of rehabilitation is restoring inde­pendence with the emphasis on activities of daily living, mobility, cognition and communication. Interventions can be applied in all stages of the dis­ease but the rehabilitation goals adjust according to the patient’s problems. The rehabilitations needs to start early enough in order to reach the established goals, prevent the complications and achieve better functional outcome.7 Symptoms of brain tumours The symptoms of brain tumours are dependent on the size and location of the tumour. They are caused by mass effect of the tumour and by the sur­rounding vasogenic brain oedema. First symptom is usually headache, which is usually worse in the morning and can be accompanied by nausea and vomiting.8 Sometimes an epileptic seizure is the first and only symptom. Each person may experi­ence symptoms differently, but motor deficits and speech disturbances are the most unpleasant be­cause they interfere with patient’s independence. Cognitive deficits are common and important be­cause they have effect on quality of life and on the efficiency of specific rehabilitation programme, but can go unnoticed for longer periods of time.9,10 Operative treatment of brain tumours Surgery is usually the first choice of treatment; the goal of surgery is maximal tumour resection, but it is also important to provide the diagnosis and prevent symptoms of the mass effect.11 In addition to microsurgery, several new techniques are used in brain tumour surgery, such as frameless, image-guided neuronavigation, preoperative functional MRI, fiber tracking and transcranial magnetic stimulation, intraoperative ultrasound and MRI, intraoperative neurophysiological monitoring (in­cluding direct cortical stimulation), fluorescence-guided removal of malignant gliomas, stereotactic needle biopsy, neuroendoscopy, awake surgery and brachytherapy. These novel techniques can help the surgeon to facilitate tumour removal, minimize the injury of the surrounding brain tissue and the occurrence of postoperative neurological deficit, thus resulting in better patient outocome.11 Postoperative period The most common complaint after surgery is fa­tigue, which improves over time, but can be intense during first weeks after surgery and also during chemotherapy or radiation therapy.12 Relatively little research on fatigue in patients undergoing surgery for malignant brain tumours has been per­formed to date.13 More severe fatigue significantly correlate with poor functional status and poorer quality of life due to impaired physical functioning and sleep disturbances.13 Patients with fatigue have problems with routine tasks - these tasks require greater concentration and effort as usually. These problems need to be considered when deciding up­on the intensity of activity during the rehabilitation program. Therefore, we plan short periods of rest during the program and assure that the patients stop with the activity before becoming overtired. Besides fatigue, cognitive functions such as at­tention, concentration and memory can be affected to a varying degree. The deficits may be temporary or more permanent, depending on whether the cause is permanent and structural or transient due to temporary brain swelling. Affective disorders must be considered immediately after surgery - they are more common in patients with the history of depression and those with coincidental physical disability.14 It is important to determine the sever­ity of the cognitive impairments and to accordingly modify the rehabilitation planning.8 Headache can last for a few days after the opera­tion and can interfere with the patients’ ability to participate in activities. Neurological deficits (pa­ralysis, weakness and balance disturbances) may also persist after the surgery. Early medical rehabilitation in Slovenia Recovery time after surgery is different for each individual. The goal of postoperative rehabilita­tion is to prevent complications and to maximize the patient’s functional abilities. Early rehabilita­tion at our institution is provided by the rehabilita­tion team, consisting of the occupational therapist working together with the physiotherapist, while the consultant of physical and rehabilitation medi­cine is responsible for proper rehabilitation pro­cedures used to help the patient return to normal activities. The rehabilitation procedures are started as soon as possible because the length of hospital stay is short (usually around 1 week) and time to achieve the goal is limited. The content, intensity and frequency of the rehabilitation programme are tailored to the individual patient’s clinical needs. Patient and his relatives are also included in the rehabilitation team, while consultants of other spe­cialisations are included as needed. 141 On the first postoperative day, provided that the control CT scan of the brain shows no significant postoperative hematoma or oedema, we start with progressive mobilisation. This is possible when the patient has good physical stamina and is with­out motor deficits. We evaluate the patient’s inde­pendence in basic daily activities and Karnofsky performance scale (KPS) is used for evaluation of patient’s functional abilities. This scale allows patients to be classified as to their functional im­pairment. The Karnofsky score runs from 100 to 0, where 100 is “perfect” health and 0 is death - the lower the score, the bigger the impairment.15 KPS may be used to determine patient’s prognosis or to measure changes in a patient’s ability to func­tion and is often used with patients suffering from malignant brain tumours.16,17 Often the patients present with cognitive deficits despite the lack of motor impairment. They would benefit from early neuropsychological treatment or at least early neuropsychological evaluation. However, this can rarely be achieved in the acute phase due to lack of clinical psychologists in hospi­tal setting in Slovenia. Neuropsychological assess­ment helps to determine whether treatment, in the form of cognitive rehabilitation or psychotherapy, may be useful after discharge from the acute hospi­tal. Outpatient programs to address cognitive defi­cits in brain tumour survivors, including cognitive therapy and pharmacologic strategies, have shown to be been beneficial.9 Patients who experience temporary or perma­nent speech difficulties require specialised therapy by the speech therapist. The speech therapist is invited into the rehabilitation team early after the operation if speech and swallowing difficulties are detected, but sufficient patient’s cooperation must be assured.18 Preliminary results of our retrospective review focusing on neurological deficits after surgery for malignant brain tumours during the past three years show that the proportion of patients with persistent neurological deficits is substantial even after surgery and in about 30% percent of patients neurological deficits could be identified at dis­charge. Neurological deficits can often be multiple, Mukand et al. described that 74.5% of patients had three or more concurrent neurologic deficits, and 39% of patients had five or more deficits, which is in accordance to our preliminary results.1 Patient with neurological deficits need special rehabilitation while they are in the acute hospital. Usually, the most important deficit for patients is motor impairment and problems with walking. Such a patient is bed-ridden and the resulting com­plications need to be prevented. In this setting, ver­ticalization is very important and there are usually no contraindications for it. We use different equip­ment to help patients sit on their bed, the tilt table is used to achieve standing and the wheelchairs are used for sitting. With the wheelchair, we enable the patient to be driven out from the room. This has a positive effect on the patient’s wellbeing, prevent­ing social isolation which may occur when the pa­tient is constantly in bed and alone in the room. With the help of a chosen neuro-physiothera­peutic technique we opt to maintain a good passive range of movement in the joints of the limbs where active movement is not possible. When increased muscle tone is present, these techniques also con­tribute to its normalization and help the patient to start using paretic limbs. Occupational therapist evaluates and treats difficulties, related to self-care and daily living and plays an important role in helping the patient develop new ways of doing different daily tasks, such as dressing, undressing, washing and eating. Often, while in the acute hos­pital, the patient is provided with individually tai­lored accessories to facilitate functioning at home (thickened cutlery handles, equipment to assist with putting on footwear etc.). Additional instruc­tions are provided to the patient and their relatives in order to improve the organization of daily living at home. Rehabilitation does not end with the patient’s discharge from the acute hospital. Hospital stays are short; at our institution, the average length of stay in the acute hospital is 9 days, which often means that the rehabilitations goals are not fully met. The patients are either discharged home or transferred to other hospitals and most of them must continue with additional oncologic treatment. University Rehabilitation Institute of the Republic of Slovenia is the only tertiary institution performing complex rehabilitation in Slovenia. Direct transferral of patient with malignant brain tumours from the acute hospital to this institution are rare, since most patients need further oncologic treatment; transferrals are thus only possible after the oncologic treatment is complete. Some patients remain very weak, dependant and immobile due to the extent of neurological and cognitive impairment. When it comes to ex­tensive neurological deficits and disturbances of consciousness with poor cooperation, our actions are mainly focused on preventing complications arising from constantly lying in bed. Special em­phasis is put on respiratory physiotherapy. It is necessary to regularly turn the patient, put him in proper positions and perform neuro-physiothera­py; electronic devices that enable joint movements and prevent contractures can also be used. Even patients in the minimally conscious state can use the wheelchair, provided it has been adapted to accommodate for passive sitting. Patients in the minimally conscious state can be stimulated with different sensory stimuli in the appropriate envi­ronmental settings, minimising additional disrup­tive stimuli from the surroundings. Relatives help in picking the appropriate stimuli and can also perform sensory stimulation during visiting hours. It is extremely important to educate the family to be able to offer good care and support to the pa­tient, especially when patients are bedridden and dependant in daily activities needing the help of other people. Often, it is also necessary to arrange for proper utilities the patient will need at home, such as an adopted bed, wheelchair, walker or lift for easier handling with bedridden patients. Such equipment can be prescribed when the patient is discharged from the hospital. Discussion Increasing incidence of brain tumours has been observed in many countries over the last thirty years.19 In assessing the outcome of malignant brain tumour patients, lift expectancy as well as direct and indirect functional impairment must also be taken into consideration. Giordana et al. have reviewed several studies dealing with the functional outcome of brain tumour patients and have shown that rehabilitation intervention offers significant benefit to this patients.20 The rehabilita­tion process is therefore of paramount importance in brain tumour patients when compared to other malignancies because of their extremely high rate of associated disability.3 Similarly, preliminary re­sults of our retrospective review have shown that approximately 30% of 200 patients being treated annually for malignant brain tumours have post­operative neurological deficits. Patients usually receive further oncologic treatment and we can assume that their functional status might worsen during additional therapy due to brain oedema or tumour progression. Recent progress in the mul­timodal treatment of brain tumour patients has improved 5 year survival rate, which has resulted in an increased number of patients requiring re­habilitation support.3 Nowadays cancer is viewed as a chronic disease where rehabilitation becomes an important aspect of care. However, despite the high incidence of neurological and functional defi­cits in brain tumour patients, rehabilitation treat­ment in this population is not as well established as it is for patients with other neurological condi­tions.7 In a study comparing brain tumour patients and patients with traumatic brain injury the au­thors found no significant differences in mobil­ity and independence in activities of daily living between both groups of patients.21 Functional im­provements are also comparable to those achieved in stroke patients.20 Clinical guidelines suggest that rehabilitation should begin early in stroke patients in order to improve the recovery process and reduce disability.22,23 In brain tumour patients, where deterioration is often faster than in stroke patients, the need for early intervention is even more pressing.7 Rehabilitation, especially during the acute phase and immediately postoperatively can improve functional outcome.7 The review of the literature by Khan et al. failed to identify and high quality studies evaluating the effectiveness of multidisciplinary rehabilitation care in patients with brain tumours.24 On the other hand, there is strong evidence that unidisciplinary interventions (exercise, physical therapy...) enhance functional outcome and improve quality of life.24 Rehabilitation is recommended in early stages of the disease for function restoration after sur­gery and in more advanced stages as an impor­tant part of palliative care with the aim to pre­vent complications, control the symptoms and maintain patients’ independence and quality of life regardless of life expectancy.25 In brain tu­mour patients, specificity of medical treatment, complication of surgery and side effects of irra­diation and chemotherapy have to be taken into consideration.26 Side effects of corticosteroids and anticonvulsants are also important, because their chronic use can be associated with myopathy, os­teoporosis, behavioural changed and psychiatric disorders.27 Anticonvulsants can affect cognitive functions, alter the reaction time and in some in­stances cause movement disorders such as ataxia; all of these side effects influence the rehabilitation process.26 In the acute phase of rehabilitation, flex­ibility and frequent reassessments are required.28 Oncologic and other treatments may impact the timing of physical therapy interventions, which should be performed in a phase of patient’s peak performance.28 Because of diverse clinical picture and varying levels of disability among brain tu­mour patients an individualised approach is al­ways warranted.29 143 With proper early medical rehabilitation in the postoperative settings we enable the patients to become more independent, prevent complica­tions and increase baseline conditions for further rehabilitation. The length of stay in the acute hos­pital setting is short and we start with rehabilita­tion procedures immediately after surgery; these procedures should be carried out throughout the additional oncologic therapy. After finishing the treatment, the patients should be evaluated and the neurological impairments, influencing daily functioning, should be identified. Further complex rehabilitation could be arranged at the University Rehabilitation Institute of the Republic of Slovenia. Several studies have shown signifi­cant improvement in the functional state of brain tumour patients as a result of in inpatient rehabili­tation.30,31 In the institutions providing inpatient rehabilitation, patients are offered individually adapted treatment programs based on their defi­cit, ability to cooperate and set goals. The chal­lenge is not just to help the patients overcome their disabilities and improve performance status but also to help them stay independent in the com­munity and lower the family burden. After finish­ing the inpatient rehabilitation, the patients may also receive appropriate rehabilitation devices to facilitate care giving at home and prolong their in­dependency. We must emphasize that an article by Goljar from 2008 shows that only about 10 patients treated for malignant brain tumours are admit­ted to the University Rehabilitation Institute of the Republic of Slovenia yearly.32 Considering large number of patients undergoing surgery and a sig­nificant proportion of postoperative neurological symptoms it remains unclear what type of reha­bilitation is offered to them after completion of the oncologic treatment. Besides motor impairments, an important po­tential long-term deficit of the surviving patients is cognitive deterioration, which is related to tu­mour location, surgical morbidity and oncologic treatment.9 Problems related to cognitive impair­ment are well documented and present even in the tumour remission period.33 However, only few studies have focused on strategies to prevent and treat cognitive deficits in brain tumour pa­tients and many of them have serious methodo­logical limitations, such as too small of a sample or retrospective study design, so further studies are necessary.33,34 Regardless of the severity, cog­nitive deficits have a significant negative impact on patient’s daily living.35 In 2003, Hahn and as­sociates published a prospective study, in which they performed standardised neuropsychologi­cal testing and life quality evaluation in primary brain tumour patients.36 The study has shown that individually tailored rehabilitation programs can increase the patient’s quality of life.36 Gehring et al. have in 2008 established that we are at a relatively early stage of development of effective pharmaco­logical and behavioural approaches towards treat­ment and prevention of cognitive deficits in this group of patients, although the approaches used might have a positive effect on other areas of pa­tient’s functioning and well-being.33 Cognitive defi­cits interfere significantly with familial, social and career-related activities.37 Recent systematic review of the literature established that neurocognitive symptoms and personality changes irreversibly al­tered the relationship between the patient and the caregiver, giving the caregiver the sense of total re­sponsibility.38 For the patient, however, loss of au­tonomy and coping with restriction seem to be the most difficult.38 Early identification of neuropsy­chological changes may lead to improved effective­ness of cognitive training.33 It has been shown that early cognitive training in the postsurgical period markedly improves cognitive functioning.33 Taking into account and treating these impairments can enhance the patients’ quality of life. Therefore, more precise evaluation of patients’ functional and cognitive state after completion of the oncologic therapy is warranted to establish criteria for fur­ther complex medical rehabilitation. Conclusions Rehabilitation of patients suffering from malignant brain tumours is an important part of treatment. By starting treatment early during hospitalization and by continuing the treatment in qualified insti­tutions later on we can raise the quality of the pa­tient’s life and achieve higher levels of independ­ence. Considering the high number of patients in Slovenia the percentage of those referred to the University Rehabilitation Institute of Slovenia after oncologic treatment is low. We believe that a more precise evaluation of the patients’ functional state after finishing additional tumour related treat­ments should be performed and more patients di­rected to the complex rehabilitation treatment. In addition to retrospective reviews, a well-designed study should be performed in Slovenia to establish the effect of inpatient postoperative rehabilitation on the quality of life in this group of patients. 144 References 1. Mukand JA, Blackinton DD, Cirncoli MG, Lee JJ, Santos BB. Incidence of neurologic deficits and rehabilitation of patients with brain tumors. Am J Phys Med Rehabil 2001; 80: 346-50. 2. Hansen A, Rosenbek Minet LK, Sogaard K, Jarden JO. The effect of an inter­disciplinary rehabilitation intervation comparing HRQoL, symptom burden and physical function among patients with primary glioma: an RTC study protocol. BMJ Open 2014; 4(10): e005490. 3. Vargo M. Brain tumor rehabilitation. Am J Phys Med Rehabil 2011; 90(5 Suppl 1): S50-62. 4. Kase M, Minajeva A, Niinepuu K, Kase S, Vardja M, Asser T, et al. Impact of CD133 positive stem cell proportion on survival in patients with glioblas­toma multiforme. Radiol Oncol 2013; 47: 405-10. 5. 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Evaluating cancer patients for rehabilitation po­tential. West J Med 1991; 155: 384-7. 18. Kos N. [Early medical rehabilitation after surger of central nervous system tumors]. [Slovenian]. In: Marinček Č, Burger H, editors. 19th rehabilitation medicine days, Ljubljana, March 28-29, 2008. Rehabilitacija 2008; 7(Suppl 2): 49-51. 19. Wrensch M, Minn Y, Chew T, Bondy M, Berger MS. Epidemiology of primary brain tumors: Current concepts and review of the literature. Neuro Oncol 2002; 4: 278-99. 20. Giordana MT, Clara E. Functional rehabilitation and brain tumour patients. A review of outcome. Neurol Sci 2006; 27: 240-4. 21. Huang ME, Cifu DX, Keyser-Marcus L. Functional outcomes in patients with brain tumor after inpatient rehabilitation: comparison of traumatic brain injury. Am J Phys Med Rehabil 2000; 79: 327-35. 22. Duncan PW, Zorowitz R, Bates B, Choi JY, Glasberg JJ, Graham GD, Katz RC, Lamberty K, Reker D. Management of adult stroke rehabilitation care: a clinical practice guideline. Stroke 2005; 36: 2100-43. 23. Bates B, Choi JY, Duncan PW, Glasberg JJ, Graham GD, Katz RC, Lamerty K, Reker D, Zorowitz R. Veterans Affairs/Department of Defense Clinical Practise Guideline for the Management of Adult Stroke rehabilitation care: executive summary. Stroke 2005; 36: 2049-56. 24. Khan F, Amatya B, Ng L, Drummond K, Olver J. Multidisciplinary rehabilita­tion after primary brain tumour treatment (review). Top Geriatr Rehabil 2011; 27: 184-92. 25. Bartolo M, Zucchella C, Pace A, De Nunzio AM, Serrao M, Sandrini G, et al. Improving neuro-oncological patients care: basic and practical concepts for nurse specialist in neuro-rehabilitation. J Exp Clin Cancer Res 2012; 31: 82. 26. Ching W, Luhmann M. Neuro-oncologic physical therapy for older person. Top Geriatr Rehabil 2011; 27: 184-92. 27. Pace A, Metro G, Fabi A. Supportive care in neurooncology. Curr Opin Oncol 2010; 22: 621-6. 28. Kirshblum S, O’Dell MW, Ho C, Barr K. Rehabilitation of persons with central nervous system tumors. Cancer 2001; 92(4 Suppl): 1029-38. 29. Sherwood PR, Given BA, Given CW, Schiffman RF, Murman DL, Lovely M, et al. Predictors of distress in caregivers of persons with a primary malignant brain tumor. Res Nursing Health 2006; 29: 105-20. 30. O’Dell MW. Barr K, Spanier D, Warnick RE. Functional outcome of inpatient rehabilitation in persons with brain tumors. Arch Phys Med Rehabil 1998; 97: 1530-4. 31. Marciniak CM, Sliwia JA, Heinemann AW, Semik PE. Functional outcomes of persons with brain tumors after inpatients rehabilitation. Arch Phys Med Rehabil 2001; 82: 457-63. 32. Goljar N. [Comprehensive rehabilitation of patients with brain tumours]. [Slovenian]. In: Marinček Č, Burger H, editors. 19th rehabilitation medicine days, Ljubljana, March 28-29, 2008. Rehabilitacija 2008; 7(Suppl 2): 52-5. 33. Gehring K, Sitskoom MM, Aaronson N, Tophoom MJB. Interventions for cog­nitive deficits in adult with brain tumours. Lancet Neurol 2008; 7: 548-60. 34. Weitzner MA, Meyers CA. Cognitive functioning and quality of life in ma­lignant glioma patients: A review of the literature. Psychooncology 1997; 6: 169-77. 35. Zucchella C, Capone A, Codella V, De Nunzio AM, Vecchione C, Sandrini G, et al. Cognitive rehabilitation for early post-surgery inpatients affected by primary brain tumor: a randomized, controlled trial. J Neurooncol 2013; 114: 93-100. 36. Hahn CA, Dunn RH, Logue PE, King JH, Edwards CL, Halperin EC. Prospective study of neuropsychologic testing and quality-of-life assessment of adults with primary malignant brain tumors. Int J Radiat Oncol Biol Phys 2003; 55: 992-9. 37. Biegler KA, Chaoul MA, Cohen L. Cancer, cognitive impairment and media­tion. Acta Oncol 2009; 48: 18-26. 38. Sterckx W, Coolbrandt A, Dierckx de Casterle B, Van den Heede K, Decruyenaere M, et al. The impact of high-grade glioma on everyday life: A systematic review from patient’s and caregiver’s perspective. Eur J Oncl Nurs 2013; 17: 107-17. 145 research article Screen-detected ductal carcinoma in situ found on stereotactic vacuum-assisted biopsy of suspicious microcalcifications without mass: radiological-histological correlation Bartlomiej Szynglarewicz1, Piotr Kasprzak2, Przemyslaw Biecek3, Agnieszka Halon4, Rafal Matkowski1,5 1 Breast Unit, Department of Surgical Oncology, Lower Silesia Oncology Centre, Wroclaw, Poland 2 Department of Breast Imaging, Lower Silesia Oncology Centre, Wroclaw, Poland 3 Faculty of Mathematics, Informatics and Mechanics, University of Warsaw, Warsaw, Poland 4 Department of Pathomorphology and Oncological Cytology, Wroclaw Medical University, Poland 5 Department of Oncology, Wroclaw Medical University, Poland Radiol Oncol 2016; 50(2): 145-152. Received 30 November 2015 Accepted 26 January 2016 Correspondence to: Bartlomiej Szynglarewicz, M.D., Lower Silesian Oncology Centre, Plac Hirszfelda 12, 53-413 Wroclaw, Poland. Phone: +48 071 368 9333; Fax: +48 071 799 8600. E-mail: szynglarewicz.b@dco.com.pl Disclosure: No potential conflicts of interest were disclosed. Background. Commonly identified on screening mammography breast microcalcifications are the predominant manifestation of ductal carcinoma in situ (DCIS). The aim of this study was to investigate the association between clinico-radiological features and histological findings in patients with screen-detected DCIS. Patients and methods. Consecutive 127 patients with pure DCIS found on stereotactic vacuum-assisted biopsy of screen-detected suspicious microcalcifications without mass entered the study. Patient age, type and distribution of microcalcifications, DCIS nuclear grade (NG) and the presence of comedonecrosis were investigated. Association between parameters was statistically analysed with P < 0.05 as a significance level. Results. Powdery microcalcifications were most often clustered while regional were most common of casting-type (P < 0.001). High, intermediate and low NG of DCIS was significantly related to casting-type, crushed stone-like and powdery microcalcifications, respectively (P < 0.01). Low and intermediate NG DCIS were the most common in clustered and grouped microcalcifications while high NG DCIS was the most often when regional distribution was observed (P < 0.05). Comedonecrosis was significantly more common in high NG DCIS (P < 0.01). The association be­tween comedonecrosis and type of microcalcifications was not significant, but with their distribution was close to the significance level (P = 0.07). Patient age was not significantly related to imaging or histological findings. Conclusions. The association between pattern of mammographic microcalcifications and histological findings re­lated to more aggressive disease can be helpful in optimal surgery planning in patients with screen-detected DCIS, regarding the extent of breast intervention and consideration of synchronous sentinel node biopsy. Key words: breast cancer screening; mammographic microcalcifications; ductal carcinoma in situ Introduction The development of imaging techniques and the widespread adoption of screening programs re­sulted in dramatically increased incidence of ductal carcinoma in situ (DCIS), which currently accounts for about 20–25% of newly diagnosed breast cancer cases.1 The most common clinical presentation of DCIS are mammographically visible microcalcifi­cations. Although being present in about 30% of all breast cancers and in approximately 55% of non-palpable breast malignancies, they are responsible for the detection of 85–95% of cases of DCIS by screening mammography.2,3 The microcalcifications associated with the de­velopment of DCIS arise in the lumen of the ter­minal ducts, by calcium production on the secre­tion material or on the zones of necrosis.4 They only indirectly attest to the cell proliferation of the carcinoma, that will then progress in the ducts in an anterograde direction toward the nipple or in a retrograde direction, within the lobule.5 The micro-calcifications are commonly discontinuous, which may indicate multifocality. However, since the true multifocal DCIS is currently believed to be a rela­tively rare condition, they most often correspond to a single lesion extending to several ducts by contiguity.4-7 With the introduction of stereotactic minimal-invasive biopsy (core-needle or vacuum-assisted) it has become possible to obtain a preop­erative diagnosis of suspicious breast microcalcifi­cations not visible on ultrasound. As most DCIS le­sions are nonalpable and some are more extensive that suspected on the mammogram, evaluation of imaging-pathologic correlation by a multidiscipli­nary team is essential in the assessment of patients to determine their eligibility for breast conserving surgery as well as to achieve in these cases a com­plete excision with negative margins and good cos­metic outcomes.8 The aim of this study was to investigate the clinical and histological features, and to evaluate the association among these findings in screen-de­tected DCIS found on stereotactic vacuum-assisted biopsy of suspicious microcalcifications. Patients and methods Screening program Nation-wide and population-based breast cancer screening program is targeting women aged 50–69, with exclusion of females undergoing treatment or being followed-up due to breast cancer. Two-view mammography (cranio-caudal and oblique) is used as a standard screening test. High-quality analogue (screen-film) or full field digital mam­mography (FFDM) are both allowed in screening program in Poland. Routine round length of the program is two years. All women with radiologi­cal findings categorised as suspicious of malig­nancy (BIRADS 4) or highly suggested for cancer (BIRADS 5) are referred to further assessment and invasive investigations. In patients with masses ul­trasound-guided core-needle or vacuum-assisted biopsy is carried out, whereas in patients with oth­er lesions, not well seen in ultrasound, a stereotac­tic biopsy under digital mammography guidance is performed. Patients A cohort of 127 consecutive non-symptomatic patients with screen-detected DCIS diagnosed in years 2009–2014 was enrolled. All of them fulfilled the study entering criteria: BIRADS category 4 or 5 microcalcifications without mass or architectural distortion, pure DCIS found on histological exami­ nation, lack of invasion or microinvasion (. 1 mm in the longest diameter ), absence of any other breast malignancy or border-line lesion. Median (mean, range) patient age was 60 years (59.6, 50–69). All the patients underwent the same type of minimal-invasive biopsy under the stereotactic guidance. Study was approved by the Independent Ethics Committee (UMED KB-376) and the Institutional Board (NDOK/668). Patients signed the informed consent. Biopsy In each case an informed consent to undergo biopsy was obtained. All the procedures were performed by one breast-dedicated radiologist (PK), in the same breast care unit, according to the same stand­ardised protocol to assure quality control. Five specimens was the minimal number of tissue cores. Each biopsy was done under the local anaesthesia using 10 cm3 of 1% lidocaine in two-step approach: 5 cm3 superficially and 5 cm3 deeply. Biopsies were completed under digital mammography guidance using a designated prone table unit (Mammotest Plus / S, Fisher Imaging, Denver, USA) with 10­G needle (EnCore Breast Biopsy System, SenoRx Inc., Irvine, CA or EnCore Enspire Breast Biopsy System, C.R. Bard Inc., Tempe, AZ). Pathology All hematoxylin and eosin stained slides of for-malin-fixed and paraffin-embedded tissue blocks were assessed by board-certified pathologists ex­perienced in breast cancer. In all the cases patho­logical examination reported pure DCIS without invasive or microinvasive component. In cases with any doubt about the origin E-cadherin im­munochemistry was used to exclude a pleomor­phic type of lobular carcinoma in situ. Evaluation of DCIS histology was performed according to the well-defined and widely accepted criteria. 147 Comedonecrosis was determined as present if the central areas of necrosis with ghost outlines of cells and cellular debris were found. Grading system was expressed by the assessment of nuclear grade (NG) categorising DCIS as low, intermediate, and high grade, based on the recommendations of the College of American Pathologists.9,10 Finally, all the slides were reviewed and re-evaluated by study supervising pathologist (AH) to confirm the original diagnosis of DCIS and its histological fea­tures as well as the absence of invasion or micro-invasion. Statistical analysis Data were collected in a prospective manner and entered a computer database. Statistical analysis was performed by professional statistician (PB). Following features were investigated: patient age, DCIS nuclear grade and the presence of comedone­crosis (as described above) as well as distribution pattern and morphology of microcalcifications. With regard to distribution pattern microcalcifica­tions were classified as clustered (< 1 cm), grouped (1–2 cm), and regional (> 2 cm). Morphological type was categorised according to Tabar classifi­cation (Figure 1–3) as powdery (cotton ball-like: indistinct, amorphous), crushed stone-like (pleo­morphic), and casting-type (linear, branching).11 Mammographic appearance was assessed before biopsy (without knowledge of the histopathologi­cal diagnosis) by two board-certified radiologists with special expertise in breast imaging (double reading) and then reviewed and re-evaluated by study supervising radiologist (PK) using analogue microfocus magnification techniques in orthogo- TABLE 1. Baseline characteristics Patient age 50–60 61–69 Microcalcifications type Powdery Crushed stone-like Casting-type Microcalcifications distribution Clustered Grouped Regional Nuclear grade (NG) NG 1 (Low) NG 2 (Intermediate) NG 3 (High) Comedonecrosis Absent Present 67 (53) 60 (47) 19 (15) 81 (64) 27 (21) 85 (67) 31 (24) 11 (9) 71 (56) 38 (30) 18 (14) 58 (46) 69 (54) nal planes or, in cases of FFDM, on-screen mag­nification. Baseline characteristics are presented in Table 1. Association between investigated vari­ables was analysed using Pearson’s chi-square test. P values less than 0.05 were considered statistically significant. Results Microcalcifications type - distribution 84% (n = 16) of powdery microcalcifications were clustered, 16% (3) were grouped, while none had regional distribution. Considering crushed stone-like and casting-type morphology 75% (61) and 30% (8) of microcalcifications were clustered, 20% (16) and 44% (12) were grouped, 5% (4) and 26% TABLE 2. Association between microcalcifications distribution and type Microcalcifications type, n [%] Powdery 16 (19) [84] 3 (10) [16] 0 (-) [-] [100%] Crushed stone-like 61 (72) [75] 16 (51) [20] 4 (36) [5] [100%] Casting type 8 (9) [30] 12 (39) [44] 7 (64) [26] [100%] (100%) (100%) (100%) P < 0.001 TABLE 3. Association between nuclear grade and microcalcifications Microcalcifications Type, n [%] Powdery 14 (20) [74] 3 (8) [16] 2 (11) [10] [100%] Crushed stone-like 47 (66) [58] 27 (71) [33] 7 (39) [9] [100%] Casting type 10 (14) [37] 8 (21) [30] 9 (50) [33] [100%] (100%) (100%) (100%) P < 0.01 Distribution, n [%] Clustered 54 (76) [64] 23 (60) [27] 8 (44) [9] [100%] Grouped 14 (20) [45] 12 (32) [39] 5 (28) [16] [100%] Regional 3 (4) [27] 3 (8) [27] 5 (28) [46] [100%] (100%) (100%) (100%) P < 0.05 (7) had regional pattern, respectively. With regard to clustered and grouped microcalcifications 19% (16) and 10% (3) were powdery, 72% (61) and 51% (16) were crushed stone-like, while 9% (8) and 39% (12) were casting-type, respectively. None of re­gional microcalcifications had powdery morphol­ogy, 36% (4) were crushed stone-like, and 64% (7) were casting-type. To sum up, powdery microc­alcifications were most often clustered, never re­gional. Similarly, just one-fourth of crushed stone-like microcalcifications were grouped or regional. Clustered microcalcifications were most rarely of casting-type while regional were most commonly. The association between morphology and distribu­tion of microcalcifications was of very high statisti­cal significance (t1 X-squared = 25.281, df = 4, P = 4.416e-05) (Table 2). Microcalcifications type - nuclear grade All over 74% (14) of powdery microcalcifications revealed DCIS with low NG, 16% (3) intermediate, and 10% (2) high NG. Crushed stone-like microc­alcifications were related to low NG in 58% (47), intermediate in 33% (27), and high in 9% (7). In contrast, 33% (9) of casting-type microcalcifications had high NG DCIS, 30% (8) intermediate, while 37% (10) had low NG DCIS. 50% (9) of high NG DCIS were presenting as casting-type microcalcifi­cations, 39% (7) as crushed stone-like, and 11% (2) as powdery. 21% (8) of DCIS with intermediate NG was found in casting-type microcalcifications, 71% (27) in crushed stone-like, and 8% (3) in powdery. With regard to low NG DCIS, 14% (10) was detect­ed in casting-type microcalcifications, while 66% (47) and 20% (14) in crushed stone-like and pow­dery, respectively. In summary, high NG DCIS was most commonly related to casting-type mi­crocalcifications while low NG DCIS most rarely. DCIS with intermediate NG was most often found in crushed stone-like microcalcifications. Just one-fourth of powdery microcalcifications revealed DCIS with NG other than low. The association be­tween morphology of microcalcifications and NG of DCIS was statistically significant (t1 X-squared = 13.363, df = 4, P = 0.009632) (Table 3). 149 Microcalcifications type -comedonecrosis Comedonecrosis was found in 47% (9) of powdery microcalcifications, 57% (46) of crushed stone-like, and in 52% (14) of casting-type. DCIS with come­donecrosis was presenting as powdery in 13% (10), crushed stone-like in 67% (46), and casting-type mi­crocalcifications in 20% (14) of cases. Considering DCIS without comedonecrosis, powdery microc­alcifications were detected in 17% (10) of patients while crushed stone-like and casting-type in 60% (35) and 23% (13), respectively. Microcalcifications type - patient age 58% (11) of patients with powdery microcalcifica­tions were 50-60 years old, whereas 54% (44) and 44% (12) of those with crushed stone-like and cast­ing-type, respectively (Table 4). Patients aged 50–60 years had powdery microcalcifications in 16% (11), crushed stone-like in 66% (44), and casting-type in 18% (12). Among older patients (61–69) pow­dery microcalcifications were present in 13% (8), crushed stone-like in 62% (37), and casting-type in 25% (15) of cases. Neither patient age nor the pres­ence of comedonecrosis was significantly related to morphology of microcalcifications (t1 X-squared = 1.0293, df = 2, P = 0.5977; t1 X-squared = 0.63551, df = 2, P = 0.7278; respectively). Microcalcifications distribution -nuclear grade In 64% (54) of clustered microcalcifications low NG DCIS was found, whereas intermediate and high NG DCIS in 27% (23) and 9% (8), respectively. Grouped microcalcifications revealed low, inter­mediate and high NG DCIS in 45% (14), 39% (12), and 16% (5) of cases while regional microcalcifica­tions in 27% (3), 27% (3), and 46% (5), respectively. 76% (54) and 60% (23) of DCIS with low and in­termediate NG were presenting as clustered micro-calcifications, 20% (14) and 32% (12) as grouped, and 4% (3) and 8% (3) as regional, respectively. Among patients with high NG DCIS 44% (8) had clustered, while 28% (5) each had grouped and re­gional microcalcifications. Summarising, low NG DCIS was the most common in clustered microc­alcifications and very rare in regional, where high NG DCIS was the most often, being found in nearly half of cases. The association between distribution of microcalcifications and NG of DCIS was statis- TABLE 4. Association between comedonecrosis and microcalcifications Microcalcifications Type, n [%] Powdery Crushed stone-like Casting type Distribution, n [%] Clustered Grouped Regional 10 (17) [53] 9 (13) [47] [100%] 35 (60) [43] 46 (67) [57] [100%] 13 (23) [48] 14 (20) [52] [100%] (100%) (100%) P > 0.5 44 (76) [52] 41 (59) [48] [100%] 12 (21) [39] 19 (28) [61] [100%] 2 (3) [18] 9 (13) [82] [100%] (100%) (100%) P 0.07 tically significant (t1 X-squared = 13.233, df = 4, P = 0.01019) (Table 3). Microcalcifications distribution -comedonecrosis In 48% (41) of patients with clustered, 61% (19) with grouped and 82% (9) with regional microcal­cifications DCIS with comedonecrosis was found. Among patients with non-comedo DCIS 76% (44) had clustered, 21% (12) had grouped, and 3% (2) had regional microcalcifications. 59% (41) of DCIS with comedonecrosis was presenting as clustered microcalcifications, while 28% (19) and 13% (9) as grouped and regional. In summary, three-fourths of patients without comedonecrosis had clustered microcalcifications while in the vast majority of pa­tients with regional microcalcifications DCIS with comedonecrosis was diagnosed. The association between distribution of microcalcifications and the presence of comedonecrosis was close but did not reach the statistical significance (t1 X-squared = 5.2275, df = 2, P = 0.07326) (Table 4). Microcalcifications distribution -patient age All over 58% (49) of patients with clustered, 39% (12) with grouped, and 55% (6) with regional mi­crocalcifications were 50–60 years old. Considering these younger patients (50–60), 73% (49), 18% (12), and 9% (6) had clustered, grouped and regional mi­crocalcifications, respectively. Among older ones (61–69) clustered microcalcifications were found in 60% (36) while grouped and regional in 32% (19) and 8% (5), respectively. Patient age was not sig­ TABLE 5. Association between nuclear grade and comedonecrosis Comedonecrosis, n [%] Absent 37 (52) [64] 20 (53) [34] 1 (6) [2] [100%] Present 34 (48) [49] 18 (47) [26] 17 (94) [25] [100%] (100%) (100%) (100%) P < 0.01 TABLE 6. Statistical significance of dependency (chi-square test, P value) Patient age — 0.5977 0.1936 0.9098 1 Microcalcifications type 0.5977 — < 0.001 < 0.01 0.7278 Microcalcifications distribution 0.1936 < 0.001 — < 0.05 0.0733 Nuclear grade 0.9098 < 0.01 < 0.05 — < 0.01 Comedonecrosis 1 0.7278 0.0733 < 0.01 — nificantly related to the distribution of microcalci­fications (t1 X-squared = 3.2839, df = 2, P = 0.1936). Nuclear grade - comedonecrosis In 94% (17) of high NG DCIS the comedonecrosis was present, whereas in 47% (18) and 48% (34) of intermediate and low NG, respectively. Among patients without comedonecrosis 2% (1) had high NG, while 34% (20) and 64% (37) had intermediate and low NG DCIS, respectively. In the group with comedonecrosis high, intermediate, and low NG DCIS were diagnosed in 25% (17), 26% (18), and 49% (34) of cases, respectively. In summary, almost all the patients with high NG DCIS had comedone­crosis while just less than half of others. In almost all the patients without comedonecrosis DCIS of low or intemediate NG was found. The association between NG and the presence of comedonecrosis was statistically significant (t1 X-squared = 13.604, df = 2, P = 0.001112) (Table 5). Nuclear grade - patient age Younger patients (50–60) had low, intermediate, and high NG DCIS in 57% (38), 28% (19), and 15% (10), while older women (61–69) in 55% (33), 32% (19), and 13% (8), respectively. In cases of high, intermediate, and low NG DCIS 56% (10), 50% (19), and 54% (38) of patients were in younger age. Patient age was not significantly related to NG of DCIS (t1 X-squared = 0.18908, df = 2, P = 0.9098). Comedonecrosis - patient age Comedonecrosis was present in 54% (36) of young­er patients and in 55% (33) of those aged 61–69 years. When comedonecrosis was absent 53% (31) of patients were 50–60 years old. Similarly, among patients with comedonecrosis 52% (36) was in younger group. The association was not significant (t1 X-squared = 0, df = 1, P = 1). Significance level of correlation between investi­gated variables is presented in Table 6. Discussion Surgery, sometimes followed by radiotherapy in cases with breast conservation, remains the treat­ment of choice in DCIS patients. Since it is highly favourable disease, there is no difference in mortal­ity rate regardless of which treatment is chosen.12 On the other hand, the extent of surgical interven­tion and the need of postoperative radiotherapy depend on some well-defined factors known to be important in predicting of local recurrence. The most significant and independent variables are quantified by the University of California/ Van Nuys Prognostic Index (USC/VNPI), which is widely used in clinical practice. USC/VNPI is a numerical algorithm combining the following prognostic factors: age at diagnosis (older age is better ), tumour size (smaller size is better ), sur­gical margin width (wider margin is better ), NG 151 (lower grade is better ), and the presence or absence of comedonecrosis (no necrosis is better ). Each of the four predictors (NG and comedonecrosis both determine pathologic classification) is scored 1 (the most favourable), 2, or 3 (the least favourable), and then added together to give an overall score, rang­ing from a low of 4 (least likely to recur ) to a high of 12 (most likely to recur ).12 However, not all these variables are available before operation (e.g. microscopic lesion diam­eter, surgical margin width). Moreover, some of features available before surgery can be underesti­mated in specimens from minimal-invasive biopsy (e.g. low/intermediate nuclear grade, absence of comedonecrosis) and eventually upgraded in the final examination of postoperative specimen. It would be helpful in surgical treatment planning if the histological characteristics could be predicted from the mammogram, particularly from the type and distribution of microcalcifications, which are the most common imaging presentation of DCIS. There are conflicting reports on whether the histological features of DCIS can be estimated by the pattern of microcalcifications found on mam­mography. Dinkel et al. found that linear branching microcalcifications tended to be associated with higher pathological grading. However, correlation was poor and not statistically significant.13 Also in a series of Slanetz and co-workers (75 cases, 62 with calcifications alone) histological grade of DCIS could not be accurately determined prospectively based on the mammographic appearance of micro­calcifications.14 In contrast, in a study of Holland and Hendriks well-differentiated DCIS was most commonly associated with multiple clusters of fine granular microcalcifications while poorly differen­tiated DCIS usually appeared on the mammogram as either linear branching or as coarse granular microcalcifications.15 It corresponds to our ob­servation that low NG DCIS is usually found in clustered microcalcifications of crushed stone-like or powdery type whereas high NG DCIS is most common in casting type microcalcifications with regional distribution. Results of more recent studies support these findings. In the large dataset consisting of 1783 DCIS (Sloane Project) casting-type microcalcifica­tions were more frequently seen in the higher grade of DCIS, occurring in 58% of high grade while in 26% of low grade cases. Moreover, casting-type mi­crocalcifications were increasingly common with increasing lesion size.16 These associations were of high statistical significance (P < 0.001). De Roos et al. reported significant association between linear microcalcifications and high grade (P < 0.001) as well as between fine granular type and low grade of DCIS (P < 0.05).8 Barreau et al. studied a large co­hort of 909 cases and found that granular or linear branching type and a number of microcalcifications higher than 20 were correlated with high grade of DCIS and the presence of comedonecrosis.17 Evans et al. noticed that when the comedonecrosis was present following features were seen more com­monly: abnormal mammogram (95% vs. 7%, P < 0.001), mammogram with calcifications (96% vs. 61%, P < 0.001), calcifications with a ductal distri­bution (80% vs. 45%, P < 0.005), and rod-shaped calcifications (83% vs. 45%, P < 0.001). In contrast, DCIS without comedonecrosis was associated with mammogram without calcifications (39% vs. 4%, P < 0.001) and predominantly punctate calcifications (36% vs. 13%, P < 0.05).18 In a series of Stomper and Connolly predominantly linear calcifications were present in 47% of DCIS with comedonecrosis com­pared to 18% of DCIS without comedonecrosis (P = 0.01) while the predominantly granular calcifica­tions in 53% and 82% (P = 0.01), respectively.19 Mammogram with microcalcifications is the most common imaging appearance of DCIS. Nevertheless, in some cases calcifications are not present. Interesting issue is to compare histological characteristics of calcified and non-calcified DCIS. As mentioned above, Evans and colleagues found that non-calcified DCIS was less commonly asso­ciated with comedonecrosis.18 Tang et al. reported that comedo DCIS had higher frequency of histo­logically seen calcifications in the ducts, however, when compared to other types it was easier to de­tect on ultrasound with not significant differences on mammography and MRI.20 Slanetz et al. noticed that DCIS presenting on mammography as only a mass was usually well-differentiated.14 In contrast, Cho et al. observed that 59% of non-calcified DCIS lesions were high grade or comedonecrosis type.21 Supporting this finding, in numerous recent stud­ies the presence of accompanying mass was related to the increased risk of invasive ductal component, which can reflect more aggressive behaviour of DCIS.22-25 In the series of Rauch et al. DCIS more frequently visible on sonography was ER-negative type, which also tended to be larger, was more likely to be high grade (93% vs. 44%, P < 0.0001) and associated with comedonecrosis (64% vs. 29%, P < 0.0001).26 Considering screen-detected DCIS, the presence of calcifications seems to be related to less favour-able histology and features associated with more aggressive behaviour. In the analysis of 217 DCIS 152 cases in 212 asymptomatic patients by Mun et al. high nuclear grade (P < 0.05), comedonecrosis (P < 0.001), and the presence of HER2/neu oncogene (P < 0.001) were more common in the calcified lesions.27 Similarly, Kim et al. noticed that calcified DCIS was significantly more often HER2-positive than ER-positive or triple-negative. Histopathologically, HER2-positive DCIS and triple-negative DCIS were more commonly associated with high nuclear grade and comedonecrosis when compared to ER-positive DCIS.28 In the era of screening programmes, advanced diagnostic tools, image-guided minimal-invasive biopsies and oncoplastic surgery a very close co­operation in multidisciplinary team is essential for the optimum management of breast cancer patients. The correlation between pattern of mam­mographic microcalcifications and histological features related to more aggressive disease can be helpful in optimal surgery planning in patients with screen-detected DCIS, with regard to the ex­tent of breast intervention and the consideration of synchronous sentinel node biopsy. Acknowledgements Authors would like to thank Ewa Kowalska for her excellent assistance in data collection and manage­ment. References 1. Ernster VL, Ballard-Barbash R, Barlow WE, Zheng Y, Weaver DL, Cutter G, et al. Detection of ductal carcinoma in situ in women undergoing screening mammography. J Natl Cancer Inst 2002; 94: 1546-54. 2. Gajdos C, Tartter PI, Bleiweiss IJ, Hermann G, de Csepel J, Estabrook A, et al. Mammographic appearance of nonpalpable breast cancer reflects patho­logic characteristics. Ann Surg 2002; 235: 246-51. 3. de Roos MA, van der Vegt B, de Vries J, Wesseling J, de Bock GH. Pathological and biological differences between screen-detected and interval ductal car­cinoma in situ of the breast. Ann Surg Oncol 2007; 14: 2097-104. 4. Holland R, Hendriks JH, Vebeek AL, Mruvanac M, Schuurmans Stekhoven JH. Extent, distribution, and mammographic/histological correlation of breast ductal carcinoma in situ. Lancet 1990; 335: 519-22. 5. Henrot P, Leroux A, Barlier C, Genin P. Breast microcalcifications: The lesions in anatomical pathology. Diagn Interv Imaging 2014; 95: 141-52. 6. Faverly DR, Burgers L, Bult P, Holland R: Three dimensional imaging of mammary ductal carcinoma in situ: clinical implications. Semin Diagn Pathol 1994; 11: 193-8. 7. Mai KT, Yazdi HM, Burns BF, Perkins DG. Pattern of distribution of intraductal and infiltrating ductal carcinoma: a three-dimensional study using serial coronal giant sections of the breast. Hum Pathol 2000; 31: 464-74. 8. de Ross MAJ, Pijnappel RM, Post WJ, de Vries J, Baas PC, Groote LD. Correlation between imaging nad pathology in ductal carcinoma in situ of the breast. World J Surg Oncol 2004; 2: 4. 9. Lester SC, Bose S, Chen YY, Connolly JL, de Baca ME, Fitzgibbons PL, et al. Protocol for the examination of specimens from patients with ductal carci­noma in situ of the breast. Arch Pathol Lab Med 2009; 133: 15-25. 10. Schwartz GF, Lagios MD, Carter D, Connolly J, Ellis IO, Eusebi V, et al. Consensus conference on the classification of ductal carcinoma in situ. Cancer 1997; 80: 1798-802. 11. Tabar L, Tot T, Dean PB. Breast Cancer: The art and science of early detection with mammography. Stuttgart, New York: Thieme; 2005. 12. Silverstein MJ, Lagios MD. Treatment selection for patients with ductal carci­noma in situ (DCIS) of the breast using the University of Southern California/ Van Nuys (USC/VNPI) Prognostic Index. Breast J 2015; 21: 127-32. 13. Dinkel HP, Gassel AM, Tschammler A. Is the appearance of microcalcifica­tions on mammography useful in predicting histological grade of malig­nancy in ductal cancer in situ? Br J Radiol 2000; 73: 938-44. 14. Slanetz PJ, Giardino AA, Oyama T, Koerner FC, Halpern EF, Moore RH, et al. Mammographic appearance of ductal carcinoma in situ does not reliably predict histologic subtype. Breast J 2001; 7: 417-21. 15. Holland R, Hendriks JH. Microcalcifications associated with ductal carci­noma in situ: mammographic-pathologic correlation. Semin Diagn Pathol 1994; 11: 181-92. 16. Evans A, Clements K, Maxwell A, Bishop H, Hanby A, Lawrence G, et al. Sloane Projest Steering Group: Lesion size is major determinant of the mammograhic features of ductal carcinoma in situ: findings from the Sloane Project. Clin Radiol 2010; 65: 181-4. 17. Barreau B, de Mascarel I, Feuga C, MacGrogan G, Dilhuydy MH, Picot V, et al. Mammography of ductal carcinoma in situ of the breast: review of 909 cas­es with radiographic-pathologic correlations. Eur J Radiol 2005; 54: 55-61. 18. Evans A, Pinder S, Wilson R, Sibbering M, et al. Ductal carcinoma in situ of the breast: correlation between mammographic and pathologic findings. AJR Am J Roentgenol 1994; 162: 1307-11. 19. Stomper PC, Connolly JL. Ductal carcinoma in situ of the breast: correla­tion between mammographic calcification and tumor subtype. AJR Am J Roentgenol 1992; 159: 483-5. 20. Tang X, Yamashita T, Hara M, Kumaki N, Tokuda Y, Masuda S. Histopathological characteristics of breast ductal carcinoma in situ and association with imag­ing findings. Breast Cancer 2015; Feb 3 [DOI10.1007/s12282-015-0592-0 Epub ahead of print]. 21. Cho KR, Seo BK, Kim CH, Whang KW, Kim YH, Woo OH, et al. Non-calcified ductal carcinoma in situ: ultrasound and mammographic findings correlated with histological findings. Yonsei Med J 2008; 49: 103-10. 22. Schulz S, Sinn P, Golatta M, Rauch G, Junkermann H, Schuetz F, et al. Prediction of underestimated invasiveness in patients with ductal carci­noma in situ of the breast on percutaneous biopsy as rationale for recom­mending concurrent sentinel lymph node biopsy. Breast 2013; 22: 537-42. 23. Park HS, Park S, Cho J, Park JM, Kim SI, Park BW. Risk predictors of underes­timation and the need for sentinel node biopsy in patients diagnosed with ductal carcinoma in situ by preoperative needle biopsy. J Surg Oncol 2013; 107: 388-92. 24. Szynglarewicz B, Kasprzak P, Halon A, Matkowski R. Preoperatively diag­nosed ductal cancers in situ of the breast presenting as even small masses are of high risk for the invasive foci in postoperative specimen. World J Surg Oncol 2015; 13: 218. 25. Bae S, Yoon JH, Moon HJ, Kim MJ, Kim EK. Breast microcalcifications: diag­nostic outcomes according to image-guided biopsy method. Korean J Radiol 2015; 16: 996-1005. 26. Rauch GM, Kuerer HM, Scoggins ME, Fox PS, Benveniste AP, Park YM, et al. Clinicopathologic, mammographic, and sonographic features in 1,187 pa­tients with pure ductal carcinoma in situ of the breast by estrogen receptor status. Breast Cancer Res Treat 2013; 139: 639-47. 27. Mun HS, Shin HJ, Kim HH, Cha JH, Kim H. Screening-detected calcified and non-calcified ductal carcinoma in situ: differences in the imaging and histo­pathological features. Clin Radiol 2013; 68: e27-35. 28. Kim MY, Kim HS, Choi N, Yang JH, Yoo YB, Park KS. Screening mammography-detected ductal carcinoma in situ: mammographic features based on breast cancer subtypes. Clin Imaging 2015; 39: 983-6. 153 research article 18F-FET and 18F-FCH uptake in human glioblastoma T98G cell lines Marco Giovanni Persico1, Federica Eleonora Buroni1, Francesca Pasi2, Lorenzo Lodola1, Carlo Aprile1, Rosanna Nano3, Marina Hodolic4 1 Department of Oncohaematology, Nuclear Medicine Unit, IRCCS San Matteo Hospital Foundation, Pavia, Italy 2 Department of Oncohaematology, Radiotherapy Unit, IRCCS San Matteo Hospital Foundation, Pavia, Italy 3 Department of Biology and Biotecnology “Lazzaro Spallanzani”, University of Pavia, Pavia, Italy 4 Nuclear medicine research department, Iason, Graz, Austria Radiol Oncol 2016; 50(2): 153-158. Received 26 November 2015 Accepted 18 March 2016 Correspondence to: Lorenzo Lodola, Fondazione IRCCS Policlinico San Matteo, V. le Golgi 19, 27100 Pavia, Italy. Phone: +39 038 250 1666; Fax: +39 0382501669; E-mail: l.lodola@smatteo.pv.it Disclosure: No potential conflicts of interest were disclosed. M.G.P., F.E.B. and F.P. have contributed equally. Background. Despite complex treatment of surgery, radiotherapy and chemotherapy, high grade gliomas often recur. Differentiation between post-treatment changes and recurrence is difficult. 18F-methyl-choline (18F-FCH) is fre­quently used in staging and detection of recurrent prostate cancer disease as well as some brain tumours; however accumulation in inflammatory tissue limits its specificity. The 18F-ethyl-tyrosine (18F-FET) shows a specific uptake in malig­nant cells, resulting from increased expression of amino acid transporters or diffusing through the disrupted blood-brain barrier. 18F-FET exhibits lower uptake in machrophages and other inflammatory cells. Aim of this study was to evaluate 18F-FCH and 18F-FET uptake by human glioblastoma T98G cells. Material and methods. Human glioblastoma T98G or human dermal fibroblasts cells, seeded at a density to obtain 2 x 105 cells per flask when radioactive tracers were administered, grew adherent to the plastic surface at 37°C in 5% CO2 in complete medium. Equimolar amounts of radiopharmaceuticals were added to cells for different incubation times (20 to 120 minutes) for 18F-FCH and 18F-FET respectively. The cellular radiotracer uptake was determined with a gamma counter. All experiments were carried out in duplicate and repeated three times. The uptake measurements are expressed as the percentage of the administered dose of tracer per 2 x 105 cells. Data (expressed as mean val­ues of % uptake of radiopharmaceuticals) were compared using parametric or non-parametric tests as appropriate. Differences were regarded as statistically significant when p<0.05. Results. A significant uptake of 18F-FCH was seen in T98G cells at 60, 90 and 120 minutes. The percentage uptake of 18F-FET in comparison to 18F-FCH was lower by a factor of more than 3, with different kinetic curves. 18F-FET showed a more rapid initial uptake up to 40 minutes and 18F-FCH showed a progressive rise reaching a maximum after 90 minutes. Conclusions. 18F-FCH and 18F-FET are candidates for neuro-oncological PET imaging. 18F-FET could be the most useful oncological PET marker in the presence of reparative changes after therapy, where the higher affinity of 18F-FCH to inflammatory cells makes it more difficult to discriminate between tumour persistence and non-neoplastic changes. Additional studies on the influence of inflammatory tissue and radionecrotic cellular components on radiopharma­ceutical uptake are necessary. Key words: Introduction there was a statement that nervous system is held together by specific cells called glia (in Greek lan-The human brain is made up of approximately guage: glia=glue). More than insulating one neu­100 billion nerve cells. Already in 19th century ron from another and prevent neuronal injury, glia supply oxygen and nutrients to neurons, destroy pathogens and remove dead neurons. In the brain, glial cells are more numerous than nerve cells (ra­tio of app. 3:1).1 Approximately 30% of all brain tumours and app. 80% of malignant ones arise from glial cell (gliomas). Different oncogenes and genetic disor­ders are most commonly mentioned as causes of gliomas. Despite complex treatment of surgery, ra­diotherapy and chemotherapy, high grade gliomas almost always recur.2,3 Before additional systemic or local therapies are performed, precise localization of recurrent tumour is essential. Differentiation be­tween postsurgical, postradiotherapy changes and recurrent tumour is still a difficult diagnostic task. Magnetic resonance imaging (MRI) is well established imaging modality for diagnosis of recurrent disease in patients with gliomas.4-6 18F-fluorodeoxyglucose (18F-FDG) Positron Emission Tomography (PET) in brain tumours was the first application of this modality in oncology7,8, however because of the high physiologic glucose uptake of normal brain tissue, 18F-FDG did not gain widespread use in brain tumours imaging.9,10 PET imaging with [11C]- and [18F]-labelled cho­line derivates is frequently used in the staging and detection of recurrent prostate cancer disease due to the increased choline kinase expression in this malignancy. Moreover, choline kinase dysregula­tion can be frequently found, not only in prostate cancer cells but in a large panel of human tumours such as lung, colorectal, and brain tumours.11-13 Following intravenous injection of choline deriva­tives in rats and mice, the brain uptake is less than 0.2% of the injected dose.14 However, choline accu­mulation in inflammatory tissue limits the specific­ity of choline PET for tumour detection.15 In the last decades, radiolabelled amino ac­ids are attracting increasing interest in nuclear medicine because amino acid tracers appear to be more specific for brain tumour imaging than trac­ers like [11C]- and [18F]-labelled choline derivates or 3,4-Dihydroxy-6-[18F]fluoro-l-phenylalanine (18F-DOPA). Results on cellular uptake of O-(2-[18F] fluoroethyl)-l-tyrosine (18F-FET) has been studied in vitro and in vivo already in the 1960’s.16 The uptake mechanism of 18F-FET in malignantly transformed cells can either be active or probably result from increased expression of amino acid transporters or passive, whereby the accumulation is slightly high­er in tumour tissue with a disrupted blood-brain barrier. In contrast to 18F and 11C-choline, 18F-FET exhibits lower uptake in machrophages and other inflammatory cells.17,18 Also 11C-methionine, la­belled amino acid for PET imaging of central nerv­ous system tumours, showed very good results. But because of short half-life of 11C (20.4 min), this tracer can be used just in the centres with on-site cyclo­tron. In the last years many articles supported state­ment that 18F-FET PET/CT is valuable modality for individual treatment decision in patients with low grade gliomas.19-24 The T98G cells are the most radio resistant cell line available derived from a human glioblastoma multiform tumour.25 T98G are arrest­ed in G1 phase under stationary phase conditions, so they also exhibit the transformed characteristics of anchorage independence and immortality.26 In our previous study27, we compared the up­take of 18F-FCH and 18F-FDG by T98G cells and fibroblasts; also for evaluation its influence on cel­lular radiopharmaceutical uptake competition ex­periments with cold choline were performed. Aim of this study was to evaluate 18F-FCH and 18F-FET uptake on T98G cell lines derived from a human glioblastoma multiforme tumour. Material and methods Cell lines Human glioblastoma T98G cells were purchased from the European Collection of Cell Cultures (ECACC, Salisbury, UK) and cultured in Eagle’s Minimum Essential Medium (EMEM, Euroclone SpA, MI, Italy) supplemented with 10% fetal bo­vine serum, 100 units/mL penicillin/streptomycin, 2 mM L-glutamine and 0.01% sodium pyruvate at 37°C in a humidified atmosphere of 5% CO2 in air. Human dermal fibroblasts were used as non-path­ological control cell types. Primary cultures of hu­man dermal fibroblasts were derived from biopsies of healthy donors after obtaining informed con­sent. Primary cultures of fibroblasts were cultured in Dulbecco’s modified Eagle’s medium (DMEM, Euroclone SpA, MI, Italy) supplemented with 10% fetal bovine serum, 100 units/mL penicillin, 100 g/ mL streptomycin, 2 mM L-glutamine at 37°C in a humidified atmosphere of 5% CO2 in air. Stock cultures of both cell lines were maintained in ex­ponential growth as monolayers in 25 cm2 Corning plastic tissue-culture flasks (Sigma-Aldrich, St Louis, MO, USA). Radioactive tracer incubation 18F-FCH and 18F-FET were obtained from IASON GmbH (Graz-Seiersberg, Austria). Synthesis of 18F-FCH was performed as follows: The precur­ 155 sor was reacted with 18F and the intermediate was evaporated via a solid phase cartridge. After the gas phase reaction, the product was trapped and puri­fied by solid phase cartridges and passed through a sterilized filter, synthesis of 18F-FET was performed as follows: The precursor (in acetonitrile) was re­acted with 18F. After 18F incorporation, acetonitrile was removed under pressure, and hydrolysis was carried out with 1 M HCl. The final solution was neutralized and purified by solid phase cartridges and passed through a sterilized filter. Cells, seeded at a density to obtain 2 x 105 cells per flask when radioactive tracers were adminis­tered, grew adherent to the plastic surface at 37°C in 5% CO2 in complete medium. Radioactive tracer experiments were performed 20-22 hours post-seeding in order to use the cells in the exponen­tial phase of growth. The medium was renewed before performing studies. Cells were incubated at 37°C with 100 kBq (100 µL) equimolar amounts of 18F-FCH or 18F-FET, added in 2 mL of medium in each flask for varying incubation times (20, 40, 60, 90, 120 min for 18F-FCH; 20, 40, 60, 80, 100, 120 min for 18F-FET) under 5% CO2 gaseous conditions. For experiments with 18F-FCH and 18F-FET, radiotracer incubation was done in complete medium. Control samples underwent the same procedure as other samples, but they were incubated with 100 µL of saline instead of a radiotracer. Cell kinetic studies and uptake evaluation The cellular radiotracer uptake was determined with a 3 x 3’’ NaI(Tl) pinhole 16 x 40 mm gamma counter (Raytest, Straubenhardt, Germany). All measurements were carried out under the same counting position along with a standardized source to verify the counter’s performance and the data were corrected for background and decay. Total ra­dioactivity was counted when the radiotracer was added to the medium in each flask (time 0). After 20, 40, 60, 90, 120 min for 18F-FCH and 20, 40, 60, 80, 100, 120 min for 18F-FET from time 0, the me­dium was harvested, the cells were rapidly washed three times with 1 mL of phosphate-buffered saline (PBS) and radiopharmaceutical uptake for each sample was assessed. All experiments were carried out in duplicate and repeated three times. The up­take measurements are expressed as the percent­age of the administered dose of tracer per 2 x 105 cells after correction for negative control uptake (flasks containing no cells with complete medium and incubated with radiopharmaceutical). FIGURE 1. Uptake of 18F-methyl-choline (18F-FCH) by T98G cells and human dermal fibroblasts. Cell viability assay At the end of quantitative gamma spectrometry, adherent cells were harvested with 1% trypsin-ED­TA solution and supernatants with adherent cells were counted with Burker’s chamber. Trypan Blue dye assay was performed to assess cell viability as standard protocol. Statistical analysis In vitro binding experiments were conducted in du­plicate and repeated three times. Data (expressed as mean values of % uptake of radiopharmaceuticals) were compared using parametric or non-paramet­ric tests as appropriate. Differences were regarded as statistically significant when p<0.05. All values are expressed as mean values with confidence in­terval CI 95% and report the uptake of radiotracers as a function of the incubation period. All values are shown as a percentage of the administered dose per 200,000 cells (mean ± CI 95%). Therefore, if error bars on the Y axis do not overlap, the two points are considered significantly different. Results Radiopharmaceuticals binding assay A significant uptake of 18F-FCH was seen in T98G cells after 60 minutes, with a percentage of uptake of 1.8 ± 0.3%, 3.6 ± 0.4% and 3.6 ± 0.6% at 60, 90 and 120 min respectively. Human dermal fibro­blasts did not seem to accumulate 18F-FCH specifi­cally; at each incubation time the percentage of the administered dose in the cells was lower than 1%. Human dermal fibroblast uptake was significantly lower than in the T98G cell uptake in all incubation times (Figure 1). FIGURE 2. Uptake of 18F-ethyl-tyrosine (18F-FET) by T98G cells. FIGURE 3. Uptake of 18F-methyl-choline (18F-FCH) and 18F-ethyl­tyrosine (18F-FET) by T98G cells. FIGURE 4. Uptake of 18F-fluorodeoxyglucose (18F-FDG), 18F-methyl-choline (18F-FCH) and 18F-ethyl-tyrosine (18F-FET) by T98G cells. Figure 2 shows the kinetic uptake of 18F-FET by T98G cells. Despite the trend represented by the curve, the uptake is quite low in terms of radiotrac­er uptake (% / 200000 cells). Figure 3 shows that the uptake by T98G cells is increased for 18F-FCH in comparison to 18F-FET. The trend of the two kinetic curves are quite dif­ferent: the uptake by T98G cells is increased for 18F-FCH over 18F-FET and the accumulation kinetic is not superimposable (see discussion). Figure 4 illustrates the comparison of 18F-FDG (data derived from our previous study27, 18F-FCH and 18F-FET uptake in T98G cells. At 40 min and at the following time points there is not overlapping of the confidence bars for 18F-FDG and 18F-FET, and the 18F-FET uptake is always lower than 18F-FDG. 18F-FCH uptake at time points after 60 min, is high­er in comparison to the other radiopharmaceuti­cals. As a negative control, flasks containing medium without cells were incubated under the same con­ditions and did not show a significant uptake of radiotracers. Cell viability Exposure to the gaseous mixture was maintained throughout the experiment and the cells’ viability was calculated to be approximately 90% under all experimental conditions (data not shown). Discussion Our research data on T98G human glioblastoma cell lines underscores the affinity of 18F-FET for ne­oplastic tissue, confirming its potential as a viable oncological PET marker. However, two aspects need to be discussed. The percentage uptake of 18F-FET in comparison to 18F-FCH was lower by a factor of more than 3. Furthermore, both tracers showed a lower uptake of radioactivity under 60 minutes in comparison to values previously reported for 18F-FDG.2 A thorough literature search did not find any studies with direct comparisons between 18F-FCH and 18F-FET uptake in glioma cell cultures. However, papers related to in vivo uptake in ex­perimental rat gliomas indicate a higher accumula­tion of 18F-FET in terms of Standard Uptake Value (SUV) as seen in both transplanted C628 or F98 glioma models29,30 in comparison to radio-labelled choline. Despite the different amounts of 18F-FCH and 18F-FET taken up by the same cell culture, the in vitro kinetic uptake is quite similar. 18F-FET did show a more rapid initial uptake up to 40 minutes and 18F-FCH showed a more progressive, continu­ous rise reaching a maximum activity plateau after 157 90 minutes. Several factors render the comparison between our results and data found in the litera­ture difficult, due to the differing characteristics of our T98G cells and other experimental cell lines. In particular, the accumulation kinetics of 18F-FET in T98G cells is quite different from that described in the 9L cancer cell line, where a wash-out is observ­able after 60 min of incubation.31 This phenomenon is less evident in F98 cell culture, with an initially fast uptake, peaking at 10 min, and followed by a nearly constant or slow wash-out rate during the incubation period of 60 min.32 On the other hand, Habermeier et al. described a progressive accumu­lation of non-radioactive FET in a NL229 human glioblastoma line up to 4 hours.33 Both Hebermaier et al.33 and Heiss et al.34 tested the release of FET. Heiss et al.34 demonstrated a quick efflux of 18F-FET from porcine SW707 colon cancer cells, only 7% of the original activity re­mained in the experimental cells after 6 min incuba­tion time, when the culture medium was replaced with a new tracer-free medium. Different results were reported by Habermeier et al.33 demonstrat­ing that, although 18F-FET is not incorporated into proteins, an intracellular metabolism could lead to another impermeable derivative trapped within the glioma cells. This would suggest an asymme­try of intra- and extracellular recognition by LAT1. The 18F-FCH kinetic pattern in our study was quite similar to that seen in 9L glioma cells35, both in the normoxic or hypoxic conditions, reaching maxi­mum activity at 120 minutes. Bansal et al.35 report­ed a negligible washout of 18F-FCH of about 13% after 2 hours in the release experiments because this radiopharmaceutical remains trapped in the cells as phospho-FCH. This demonstrates the slow rate of dephosphorylation. Conversely, apparent discrepancies between our in vitro observations and the in vivo glioma rat model emerged, both in terms of relative uptake and tracer kinetics. These mismatches could be explained by different caus­es, including radiotracer accumulation detected by the external imaging device or direct measure­ment of the pathological specimen, which provides information not only of the true tumour uptake but also of the inflammatory cells. In this setting, 18F-FET accumulates predominantly in the tumour rather than in inflammatory cells, differing from 11C-MET and suggesting that different subtypes of the L system are involved.36 Contrarily, 18F-FCH ac­cumulation has been demonstrated in brain radia­tion injuries and in murine atherosclerotic plaques - probably mediated by macrophages - as well as in a turpentine-induced sterile abscess.37,38 In a rat model of acute brain injury (cryolesion and proton-induced necrosis) 18F-FET uptake was mainly due to the disruption of the blood-brain-barrier while 18F-FCH was additionally taken up by inflamma­tory cells.39 Similarly, a comparison of 18F-FCH and 18F-FET in a rat glioma radionecrosis indicated 18F-FET as the superior discriminant between via­ble tumour and inflammatory changes30, although evidence of increased 18F-FET uptake in perilesion­al reactive astrogliosis after radiotherapy could lead to an overestimation of tumor size.40 Conclusions The in vitro model used in these experiments allows direct comparison of different radiopharmaceuti­cals as potential candidates for neuro-oncological PET imaging. The results obtained indicate a supe­riority of 18F-FCH in terms of absolute uptake and in obtaining an optimal target to non-target ratio in the brain, whereas the major limitation of 18F-FDG is its physiological parenchymal uptake. However, a direct translation to clinical application is ham­pered by certain conflicting results reported in the literature. 18F-FET could be more useful in the pres­ence of reparative changes after therapy, where the higher affinity of 18F-FCH to inflammatory cells makes it more difficult to discriminate between tumour persistence and non-neoplastic changes. Additional studies on the influence of inflamma­tory tissue and radionecrotic cellular components on radiopharmaceutical uptake will be necessary to elucidate these topics. References 1. Purves D, Augustine GJ, Fitzpatrick D, Katz LC, LaMantia AS, McNamara JO, et al. Neuroscience (2nd edition). Sunderland (MA): Sinauer Associates; 2001. 2. 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Treatment-related change versus tumor recurrence in high-grade gliomas: a diagnostic conundrum--use of dynamic susceptibility contrast-enhanced (DSC) perfu­sion MRI. AJR Am J Roentgenol 2012; 198: 19-26. 158 7. Patronas NJ, Di Chiro G, Brooks RA, DeLaPaz RL, Kornblith PL, Smith BH, et al. Work in progress: [18F] fluorodeoxyglucose and positron emission tomography in the evaluation of radiation necrosis of the brain. Radiology 1982; 144: 885-9. 8. Di Chiro G, Oldfield E, Wright DC, De Michele D, Katz DA, Patronas NJ, et al. Cerebral necrosis after radiotherapy and/or intraarterial chemotherapy for brain tumors: PET and neuropathologic studies. AJR Am J Roentgenol 1988; 150: 189-97. 9. Wong TZ, van der Westhuizen GJ, Coleman RE. Positron emission tomogra­phy imaging of brain tumors. Neuroimaging Clin N Am 2002; 12: 615-26. 10. Olivero WC, Dulebohn SC, Lister JR. The use of PET in evaluating patients with primary brain tumors: Is it useful? 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Wyss MT, Weber B, Honer M, Späth N, Ametamey SM, Westera G, et al. 18F-choline in experimental soft tissue infection assessed with autoradiogra­phy and high-resolution PET. Eur J Nucl Med Mol Imaging 2004; 3: 312-6. 16. Oxender DL, Christensen HN. Distinct mediating systems for the transport of neutral amino acids by the Ehrlich cell. J Biol Chem 1963; 238: 3686-99. 17. Kaim AH, Weber B, Kurrer MO, Westera G, Schweitzer A, Gottschalk J, et al. 18F-FDG and 18F-FET uptake in experimental soft tissue infection. Eur J Nucl Med 2002; 29: 648-54. 18. Buck D, Förschler A, Lapa C, Schuster T, Vollmar P, Korn T, et al. 18F-FDG PET detects inflammatory infiltrates in spinal cord experimental autoimmune encephalomyelitis lesions. J Nucl Med 2012; 53: 1269-76. 19. Messing-Jünger AM, Floeth FW, Pauleit D, Reifenberger G, Willing R, Gärtner J, et al. Multimodal target point assessment for stereo-tactic biopsy in children with diffuse bithalamic astrocytomas. Child’s Nerv Syst 2002; 18: 445-9. 20. Pauleit D, Floeth F, Tellmann L, Hamacher K, Hautzel H, Müller HW, et al. Comparison of O-(2-18F-fluoroethyl)-L-tyrosine PET and 3-123I-iodo-alpha­methyl-L-tyrosine SPECT in brain tumors. J Nucl Med 2004; 45: 374-81. 21. Pöpperl G, Goldbrunner R, Gildehaus FJ, Kreth FW, Tanner P, Holtmannspötter M, et al. O-(2-(18F)fluoroethyl)-L-tyrosine PET for monitoring the effects of convection-enhanced delivery of paclitaxel in patients with recurrent glio­blastoma. Eur J Nucl Med Mol Imaging 2005; 32: 1018-25. 22. Pöpperl G, Götz C, Rachinger W, Schnell O, Gildehaus FJ, Tonn JC, et al. Serial O-(2-[(18)F]fluoroethyl)-L:-tyrosine PET for monitoring the effects of intracavitary radioimmunotherapy in patients with malignant glioma. Eur J Nucl Med Mol Imaging 2006; 33: 792-800. 23. Piroth MD, Pinkawa M, Holy R, Klotz J, Nussen S, Stoffels G, et al. Prognostic value of early [18F]fluoroethyltyrosine positron emission tomography after radiochemotherapy in glioblastoma multiforme. Int J Radiat Oncol Biol Phys 2011; 30: 176-84. 24. Wyss M, Hofer S, Bruehlmeier M, Hefti M, Uhlmann C, Bärtschi E, et al. Early metabolic responses in temozolomide treated low-grade glioma patients. J Neurooncol 2009; 95: 87-93. 25. Yao KC, Komata T, Kondo Y, Kanzawa T, Kondo S, Germano IM. Molecular response of human glioblastoma multiforme cells to ionizing radiation: cell cycle arrest, modulation of the expression of cyclin-dependent kinase inhibi­tors, and autophagy. J Neurosurg 2003; 98: 378-84. 26. Stein GH. T98G: an anchorage-independent human tumor cell line that exhibits stationary phase G1 arrest in vitro. J Cell Physiol 1979; 99: 43-54. 27. Buroni FE, Pasi F, Persico MG, Lodola L, Aprile C, Nano R. Evidence of 18F-FCH uptake in human T98G glioblastoma cell line. Anticancer Res 2015; 35: 6443­ 8. 28. Wyss MT, Spaeth N, Biollaz G, Pahnke J, Alessi P, Trachsel E, Treyer V, et al. Uptake of 18F-Fluorocholine, 18F-FET, and 18F-FDG in C6 gliomas and cor­relation with 131I-SIP(L19), a marker of angiogenesis. J Nucl Med 2007; 48: 608-14. 29. Spaeth N, Wyss MT, Pahnke J, Biollaz G, Lutz A, Goepfert K, et al. Uptake of 18F-fluorocholine, 18F-fluoro-ethyl-L:-tyrosine and 18F-fluoro-2-deoxyglucose in F98 gliomas in the rat. Eur J Nucl Med Mol Imaging 2006; 33: 673-82. 30. Bolcaen J, Descamps B, Deblaere K, Boterberg T, De Vos Pharm F, Kalala JP, et al. (18)F-fluoromethylcholine (FCho), (18)F-fluoroethyltyrosine (FET), and (18)F-fluorodeoxyglucose (FDG) for the discrimination between high-grade glioma and radiation necrosis in rats: a PET study. Nucl Med Biol 2015; 42: 38-45. 31 Wang L, Lieberman BP, Ploessl K, Kung HF. Synthesis and evaluation of 18F labelled FET prodrugs for tumor imaging. Nucl Med Biol 2014; 41: 58-67. 32. Wang HE, Wu SY, Chang CW, Liu RS, Hwang LC, Lee TW, et al. Evaluation of F-18-labeled amino acid derivatives and [18F]FDG as PET probes in a brain tumor-bearing animal model. Nucl Med Biol 2005; 32: 367-75. 33. Habermeier A, Graf J, Sandhöfer BF, Boissel JP, Roesch F, Closs EI. System L amino acid transporter LAT1 accumulates O-(2-fluoroethyl)-L-tyrosine (FET). Amino Acids 2015; 47: 335-44. 34. Heiss P, Mayer S, Herz M, Wester HJ, Schwaiger M, Senekowitsch-Schmidtke R. Investigation of transport mechanism and uptake kinetics of O-(2-[18F] fluoroethyl)-L-tyrosine in vitro and in vivo. J Nucl Med 1999; 40: 1367-73. 35. Bansal A, Shuyan W, Hara T, Harris RA, Degrado TR. Biodisposition and metabolism of [(18)F]fluorocholine in 9L glioma cells and 9L glioma-bearing fisher rats. Eur J Nucl Med Mol Imaging 2008; 35: 1192-203. 36. Stöber B, Tanase U, Herz M, Seidl C, Schwaiger M, Senekowitsch-Schmidtke R. Differentiation of tumour and inflammation: characterisation of [methyl­3H]methionine (MET) and O-(2-[18F]fluoroethyl)-L-tyrosine (FET) uptake in human tumour and inflammatory cells. Eur J Nucl Med Mol Imaging 2006; 33: 932-9. 37. van Waarde A, Elsinga PH. Proliferation markers for the differential diagnosis of tumor and inflammation. Curr Pharm Des. 2008; 14: 3326-39. 38. Langen KJ, Hamacher K, Weckesser M, Floeth F, Stoffels G, Bauer D, et al. O-(2-[18F]fluoroethyl)-L-tyrosine: uptake mechanisms and clinical applica­tions. Nucl Med Biol 2006; 33: 287-94. 39. Spaeth N, Wyss MT, Weber B, Scheidegger S, Lutz A, Verwey J, et al. Uptake of 18F-fluorocholine, 18F-fluoroethyl-L-tyrosine, and 18F-FDG in acute cerebral radiation injury in the rat: implications for separation of radiation necrosis from tumor recurrence. J Nucl Med 2004; 45: 1931-8. 40. Piroth MD, Prasath J, Willuweit A, Stoffels G, Sellhaus B, van Osterhout A, et al. Uptake of O-(2-[18F]fluoroethyl)-L-tyrosine in reactive astrocytosis in the vicinity of cerebral gliomas. Nucl Med Biol 2013; 40: 795-800. 159 research article Imaging of human glioblastoma cells and their interactions with mesenchymal stem cells in the zebrafish (Danio rerio) embryonic brain Milos Vittori1, Barbara Breznik1,2, Tajda Gredar3, Katja Hrovat1,3, Lilijana Bizjak Mali3, Tamara T. Lah1,4 1 Department of Genetic Toxicology and Cancer Biology, National Institute of Biology, Ljubljana, Slovenia 2 Jozef Stefan International Postgraduate School, Ljubljana, Slovenia 3 Department of Biology, Biotechnical Faculty, University of Ljubljana, Ljubljana, Slovenia 4 Department of Chemistry and Biochemistry, Faculty of Chemistry and Chemical Technology, University of Ljubljana, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 159-167. Received 3 December 2015 Accepted 7 February 2016 Correspondence to: Miloš Vittori, Department of Genetic Toxicology and Cancer Biology, National Institute of Biology, Večna pot 111, SI-1000 Ljubljana, Slovenia. Phone: +386 59 232 884; Fax: +386 59 232 715; E-mail: milos.vittori@gmail.com Disclosure: No potential conflicts of interest were disclosed. Background. An attractive approach in the study of human cancers is the use of transparent zebrafish (Danio rerio) embryos, which enable the visualization of cancer progression in a living animal. Materials and methods. We implanted mixtures of fluorescently labeled glioblastoma (GBM) cells and bone­marrow-derived mesenchymal stem cells (MSCs) into zebrafish embryos to study the cellular pathways of their invasion and the interactions between these cells in vivo. Results. By developing and applying a carbocyanine-dye-compatible clearing protocol for observation of cells in deep tissues, we showed that U87 and U373 GBM cells rapidly aggregated into tumor masses in the ventricles and midbrain hemispheres of the zebrafish embryo brain, and invaded the central nervous system, often using the ven­tricular system and the central canal of the spinal cord. However, the GBM cells did not leave the central nervous system. With co-injection of differentially labeled cultured GBM cells and MSCs, the implanted cells formed mixed tumor masses in the brain. We observed tight associations between GBM cells and MSCs, and possible cell-fusion events. GBM cells and MSCs used similar invasion routes in the central nervous system. Conclusions. This simple model can be used to study the molecular pathways of cellular processes in GBM cell inva­sion, and their interactions with various types of stromal cells in double or triple cell co-cultures, to design anti-GBM cell therapies that use MSCs as vectors. Key words: brain tumors; tumor microenvironment; animal models; xenotransplantation Introduction Glioblastoma multiformae (GBM) is the most ag­gressive type of glioma and also the most frequent and fatal among brain tumors.1 An essential hall­mark of GBM is its diffuse invasion into the brain parenchyma, which prevents successful surgical removal.2 Understanding the mechanisms and the pathways of GBM cell invasion is therefore of crucial importance for the treatment of the ag­gressive spread of GBM.1-3 The process of GBM cell infiltration into the brain parenchyma4 differs from carcinoma cells invading the more compact extracellular matrix and the basal membranes of blood vessels.5,6 The recently recognized impor­tant role of the tumor microenvironment in cancer cell invasion7 has become an important topic and the subject of intensive research.8-10 The effects of the microenvironment also include the impact of the different types of cells comprising the stroma within a tumor mass. Infiltrating and tumor-asso­ciated mesenchymal stem cells (MSCs) may sig­nificantly affect tumor progression and resistance to treatment, as reviewed in.8,11 MSCs are known to be recruited by tumor-secreted signaling mol­ecules via the blood circulation, and to become part of the tumor-supporting stroma, where they have a role that remains poorly understood.10,12 Several studies have addressed this issue in vitro and in vivo, also by using genetically modified MSCs.13,14 Previously, we studied the molecular mechanisms that support the observed phenotype changes in GBM cells and MSCs upon co-culture in vitro, in­cluding decreased U87 GBM cell proliferation and invasion, and increased U373 GBM cell invasion in vitro.15,16 By investigating the GBM-MSC inter­actions in a mouse model, Behnan et al.17 recently showed that cells with an MSC-like phenotype can infiltrate the stroma of the mouse GBM and have important roles in tumor cell growth. Moreover, their data demonstrated an alteration in GBM cell marker expression upon the encounter with MSCs in vivo. In the present study, we aimed to use an al­ternative and simpler in vivo GBM xenotransplan­tation model in zebrafish embryos18, to study hu­man GBM cell invasion and their interactions with MSCs at the cellular level. The zebrafish (Danio rerio) is the major verte­brate model in developmental biology and genet­ics.19 There are several technologies available in the zebrafish that have made it a unique model in can­cer research.20 In particular, cancers can be studied throughout the life cycle of zebrafish, with each ze­brafish developmental stage offering its own exper­imental advantages. This makes zebrafish a power­ful complement to other more traditional model systems.21 As well as their high fecundity and ease of maintenance, the major advantage of zebrafish is the transparency of their embryos and larvae, which allows in vivo visualization of cellular pro­cesses related to cancer growth and progression at single-cell resolution.20,22,23 Xenotransplantation of either dye-labeled or fluorescent-protein-express­ing human cells in zebrafish embryos is becoming an increasingly used tool to study cancers of the central nervous system (CNS).18,24-26 The aim of the present study was to investigate the interactions of GBM cells with the brain matrix components and MSCs in the zebrafish embryonic brain by co-implantation of fluorescently labeled GBM cells and MSCs. To deepen our understand­ing of GBM cell behavior within the brain of ze­brafish embryos, we combined in vivo imaging of GBM progression with imaging of fluorescently counterstained whole-mount preparations that al­lowed the visualization of the anatomical context of the implanted cells. As chemical fixation leads to loss of transparency of the embryonic tissues, it ne­cessitated the clearing of the embryos, which was achieved with the use of clearing agents.27-39 To this end, we optimized and applied protocols to clear fixed tissues while preserving the fluorescent pro­tein signal over a period of several weeks. Materials and methods Ethical statement The experimental procedures were approved by the Republic of Slovenia National Medical Ethics Committee, approval No. 92/06/12. All of the pro­cedures were performed according to the relevant regulations. Zebrafish husbandry Wild-type AB zebrafish (Danio rerio) were maintained under conditions according to the Organisation for Economic Cooperation and Development guidelines.40 The zebrafish embryos were collected and incubated in dilution water (ISO 7346-3:1996) with 0.005% phenylthiourea, to inhibit pigment formation after 36 h of age. Human cells The U373 and U87-MG human GBM cell lines were from American Type Culture Collection (USA), and the BM-MSC2 human bone-marrow-derived MSC cell line was from Lonza Bioscience (USA). The cells were cultured in Dulbecco’s modified Eagle’s medium (Sigma-Aldrich, USA) supple­mented with 10% fetal bovine serum (Gibco, USA), 100 U/mL penicillin (Sigma-Aldrich), 100 mg/mL streptomycin (Sigma-Aldrich), 2 mM L-glutamine (Sigma-Aldrich), 1 mM Na-pyruvate (Gibco), and non-essential amino acids (Sigma-Aldrich). Xenotransplantation procedures The U373 GBM cells were transfected with the pEGFP-N1 plasmid to stably express enhanced green fluorescent protein (GFP). The U87 GBM cells were transfected for the expression of the red fluorescent protein DsRed, as described previ­ously.16 Cells were transfected using the Superfect Transfection Reagent (Qiagen, Germany) by 3 h pre-incubation at 37°C, 5% CO2. The transfection 161 TABLE 1. Compositions of the selected optical clearing agents SeeDB 80% (w/w) fructose, 0.5% (w/w) .-thioglycerol in water Ke et al.34 sRIMS 70% (w/v) sorbitol, 0.01% (w/v) sodium azide, 0.1% (w/v) Tween 20 in 0.02 M phosphate buffer (pH 7.5) Yang et al.39 ScaleA2 4 M urea, 0.1% (w/v) Triton X-100, 10% (w/w) glycerol in water Hama et al.33 ScaleU2 4 M urea, 0.1% (w/v) Triton X-100, 30% (w/w) glycerol in water Hama et al.33 mix was then removed and upon washing with phosphate-buffered saline (PBS), fresh culture medium was added to the cells. Transfected cells were selected for by adding 0.8 mg/ml Geneticin (G418, Gibco, USA) to the medium. The uniformity of emitted fluorescence was confirmed with flow cytometry. The stability of fluorescent protein ex­pression was verified with repeated flow cytome­try analyses after 10 and 20 passages and proved to be stable (>99% of fluorescent protein-expressing cells). Prior to implantation, MSCs were labeled with Vybrant DiI or DiO (Molecular Probes, USA) for co-implantation with the U373 and U87 cells, re­spectively, according to the manufacturer instruc­tions. For injection into the embryos, suspensions of GBM cells prepared in PBS were mixed with la­beled MSCs in a 1:1 ratio. Embryos at 52 h after fer­tilization were injected either with 50 to 100 GBM cells or 100 to 200 cells of the GBM/MSC mixture (i.e., maintaining 50-100 GBM cells), using a bo­rosilicate glass capillary and a MICROINJECTOR system (Tritech Research, USA). After cell implan­tation, the embryos were incubated at 31°C in 48-well plates for 3 days. Clearing agents The clearing agents used were SeeDB, a near-sat­urated solution of fructose with .-thioglycerol34, sRIMS, a buffered solution of sorbitol39, and two aqueous solutions of urea and glycerol known as ScaleA2 and ScaleU2.33 An overview of the compo­sitions of these clearing agents is shown in Table 1. Analysis of clearing efficiency and fluorescence preservation At 3 days after fertilization (for measurements of transparency and size) and 5 days after fertilization (for fluorescence imaging of implanted cells), the zebrafish embryos were fixed in 4% paraformalde­hyde at 4°C overnight, after which time the fixative was washed off with PBS. The fixed embryos were then embedded in 2% low-melting-point agarose in PBS in 50-mm Petri dishes. For the optical clear­ing agent SeeDB, the embryos were transferred to SeeDB through a graded series of sucrose, as de­scribed by Ke et al.34, and maintained at room tem­perature. For sRIMS and Scale, the embryos were immersed in the clearing agents and kept at 4°C in the dark. In all cases, the clearing agents were replaced every 3 days. The control embryos were incubated in parallel in PBS. For analysis of the whole-embryo clearing, transmitted light images were obtained at constant (maximum) illumina­tion at 32× magnification. For imaging and quan­tification of GFP fluorescence, the images were captured at 80× magnification using the GFP fil­ter set. Micrographs were obtained using a fluo­rescence stereomicroscope (Leica MZ FLIII). The imaging was carried out over a period of 21 days. The analysis of fluorescence preservation was per­formed on embryos with implanted U373 cells. Fluorescence intensity, embryo transparency, and embryo size were quantified with the image analy­sis software ImageJ.41 For determination of embryo transmittance, the parameter ‘Integrated density’ was measured. The relative integrated densities and areas were determined by dividing the values of these parameters at the given time points with their values at the beginning of the observation on day 0. As integrated density represents the prod­uct of pixel intensities and area, the changes in em­bryo size that were caused by some of the clearing agents were accounted for by dividing the integrat­ed density of the structure analyzed with its area, thus obtaining the relative embryo transparency. Fluorescence intensity was analyzed by threshold­ing the fluorescent images with a constant thresh­old and measuring the integrated density of the se­lection. For the analysis of changes in embryo size and transparency, 8 embryos per treatment were measured. For the analysis of GFP fluorescence intensity changes, 24 embryos per treatment were measured. Measurements were compared with ANOVA in GraphPad Prism. 162 Confocal microscopy The nuclei of the embryos that had been fixed, em­bedded in agarose, and cleared as described above were counterstained by addition of 0.004% methyl green to the individual clearing agent.42 Confocal z-stacks of the embryos were obtained using a spec­tral confocal laser scanning microscope (Leica TCS SPE) at 10× magnification after 7 days of treatment. Results Clearing efficiencies of the different clearing agents To evaluate the applicability of the different optical clearing agents (Table 1) to zebrafish embryo imag­ing, we treated embryos fixed at 3 days after ferti­lization with SeeDB, sRIMS, ScaleA2, and ScaleU2 for 3 weeks, with regular imaging. The tissues were cleared best by ScaleU2 and ScaleA2 with no statis­tically significant difference between them at any time point. These agents performed significantly better than SeeDB on all treatment days. The least effective agent was sRIMS (Figure 1A). After ap­proximately 1 week of incubation, fructose began to crystallize from the SeeDB solution, preventing further analyses. With regard to the preservation of GFP fluorescence, ScaleU2 was the optimal clear- FIGURE 1. (A) Clearing of zebrafish embryos. Embryos were fixed 3 days after fertilization, exposed to the different clearing agents SeeDB, sRIMS, ScaleA2, and ScaleU2 for 21 days, and imaged regularly. Time courses of changes in relative transparency are shown, which represents the value of integrated density relative to day 0 divided by the embryo area relative to day 0. Differences between treatments are statistically significant in all cases except between ScaleA2 and Scale B2 (on all days) and between ScaleA2 and sRIMS on day 21. Green, SeeDB; purple, sRIMS; dark blue, ScaleA2; red, ScaleU2; light blue, PBS control. Data for the different clearing agents are displaced horizontally for improved clarity. Means ± SE of eight embryos per treatment are shown. (B) Preservation of GFP fluorescence during clearing. Changes in the detected GFP fluorescence intensity of glioblastoma cells implanted in the brain of zebrafish embryos during treatment with different clearing agents of SeeDB, sRIMS, ScaleA2, and ScaleU2, measured over 21 days of the treatment. The integrated density of GFP-expressing cells relative to day 0 was measured. Fluorescence intensity was significantly increased compared to control in the case of ScaleU2 on all days except on day 3, but not in the case of other clearing agents. Means ±SE of 24 embryos per treatment are shown. (C) Fluorescence of U373­GFP cells in the brain of zebrafish embryos. Representative images show embryos treated with the different clearing agents obtained at the beginning of observation (Day 0, left) and after 3 days of clearing (Day 3, right). The appearance of autofluorescence of the yolk (arrow) is evident in the case of SeeDB. Scale bar: 400 µm. 163 ing agent, resulting in a several-fold increase in fluorescence intensity during the first 3 days of in­cubation and no demonstrable reduction in its in­tensity during 3 weeks of observation (Figure 1B). These changes were statistically significant when compared with the control. Complete loss of flu­orescence occurred in the case of SeeDB within a week and no statistically significant increases in in­tensity compared to the control were demonstrated in the cases of ScaleA2 and sRIMS. The loss of GFP fluorescence in SeeDB was accompanied by the appearance of strong autofluorescence of the yolk and eye (Figure 1C). Localization of implanted glioblastoma cells and pathways of GBM cell invasion in the zebrafish embryonic brain After selecting ScaleU2 as the optimal clearing agent for the visualization of the fluorescent-pro­tein-labeled cells, it was applied to visualize tumor progression in the whole-mount preparations of the zebrafish embryos. We implanted U373-GFP cells into the brain of embryos 2 days after fertili­zation, and monitored these over the following 3 days. By imaging the GBM cells in zebrafish embryos in vivo, we demonstrated that implanted cells ag­gregated and formed tumors in the zebrafish brain (Figure 2A). In some embryos, individual cells moved posteriorly in the embryo at great speed, as they progressed at several hundreds of microm­eters per day (Figure 2B). This rapid invasion out­side of the brain in the posterior direction was ob­served more frequently for the U87 cells (35 ± 5% of the embryos, as 3 experimental repeats, and 20 embryos per repeat) than for the U373 cells (20 ± 5% of the embryos, as 3 experimental repeats, and 20 embryos per repeat). Tumors were seen to form predominantly in the midbrain hemispheres and in the ventricles of the midbrain and hindbrain (Figure 3A–C). Individual cells, or small strands of cells, invaded the ventric­ular system and the brain tissue using pseudopo­dal movement (Figure 3A,B). In particular, cells present in the midbrain hemispheres formed elon­gated pseudopodia and invaded the neighboring brain areas dorsally, most likely along axonal tracts that connect the hemispheres (Figure 3A). Whole-mount imaging of embryos with cells invading posteriorly in the body revealed that the rapidly in­vading cells invaded the spinal cord via the central canal (Figure 3D,E). We did not observe GBM cells outside of the brain and spinal cord, indicating that GBM cell invasion in zebrafish embryos was lim­ited to the CNS, and that the cells did not spread via the circulatory system. Imaging of xenotransplanted GBM and MSC co-cultures To study the interactions between the GBM cells and MSCs in vivo, we implanted co-cultures of U373-GFP cells and carbocyanine-dye-labeled hu­man MSCs into the brain of zebrafish embryos 2 days after fertilization. As labeling with carbocya­nine dyes relies on the hydrophobic nature of these dyes, they can be washed out with organic sol­ FIGURE 3. Visualization of GBM cells in cleared zebrafish embryos, counterstained with methyl green (presented in blue). Embryos with U373-GFP and U87-DsRed cells implanted in the brain were cleared with ScaleU2, counterstained with methyl green, and imaged with confocal microscopy. (A) U87-DsRed cells (arrows) in the brain of a zebrafish embryo 3 days after implantation. (B) An optical section through the tumor in (A), demonstrating that the tumor is a compact mass of U87 cells in the midbrain ventricle. (C) U373-GFP cells (arrows) in the brain of a zebrafish embryo 3 days after implantation. Elongated U373-GFP cells are visible invading from the tumor (asterisk). (D) A U373-GFP cell invading along the central canal of the spinal cord (arrow), in dorsal view. (E) A U373-GFP cell invading along the central canal of the spinal cord (arrow), in lateral view. Scale bars: 70 µm (A, B, C); 50 µm (D, E). vents and detergents. Thus, we prepared ScaleU2 without Triton X-100, with which we successfully visualized dye-labeled cells in whole-mount prep­arations. In implanted mixtures of GBM cells and MSCs, the MSCs preferentially associated with the implanted GBM cells instead of being interspersed individually or as separate clusters in the brain (Figure 4A–C). The MSCs often used similar inva­sion routes as the GBM cells, as they moved along the ventricles and the central canal of the spinal cord (Figure 4B,C). Confocal imaging of U373 and MSC co-cultures in situ revealed that the GBM cells and MSCs formed mixed tumor masses that consisted of both of these cell types in similar locations as for the GBM cells alone; i.e., in the ventricles and midbrain hemispheres (Figure 4A,B). These two cell types were interspersed in these tumors, and interacted closely with each other (Figure 4D). In some cases, cells simultaneously emitting the fluorescence of proteins and the carbocyanine dye were observed, which indicated possible cell fusion between the GBM cells and MSCs (Figure 5). Discussion The major advantage of the zebrafish model is the transparency of their embryos and larvae, which allows in vivo visualization of cellular processes related to cancer progression at single-cell resolu­tion. We identified ScaleU2 as the optimal clear­ing agent for zebrafish embryos among the agents tested. Furthermore, we were able to modify it to be compatible with the labeling of cells with carbo­cyanine dyes. The superiority of ScaleU2 in fluores­cence preservation appears to result from its high glycerol concentration, and thus might be linked to the protein-stabilizing effects of glycerol in aque­ous solution.43,44 The proposed protocols were used to study the invasion of the U87 and U373 human GBM cell lines alone and in co-cultures with bone-marrow­derived MSCs in the zebrafish embryo. By combin­ing the in vivo imaging with confocal microscopy of fluorescently counterstained whole-mount prepa­rations, we demonstrated that GBM cells aggregate in the brain of zebrafish embryos and form tumors predominantly in the ventricles. This indicates that GBM cells have tropism towards each other upon implantation to form tumors, which are prefer­entially formed in the ventricles and dorsal areas of the midbrain. The tendency of the GBM cells to aggregate in these areas might be linked to the ease of dislodging the embryonic brain tissues in anatomical structures such as the ventricles, which are fluid-filled spaces where the brain cells are not in direct contact. The localization of GBM cells to the ventricular system has previously not been re­ported. Eden et al.45 recently reported that mouse xenografts in the brain of juvenile (30-day-old) ze­brafish reproduced the histology and gene expres­sion profiles of the murine tumors of their origin within the tissues of the brain. Thus, the observed localization of the GBM cells to the ventricular sys­tem might be limited to embryos and larval stages. We were able to identify the central canal of the spinal cord as the major route of GBM invasion in zebrafish embryos that has not been reported before. Furthermore, GBM cells did not leave the central nervous system, which is similar to their behavior in humans.46 In a previous study on mu­rine tumor xenografts in the zebrafish brain, tumor masses developed 1 day to 2 days after the im­ 165 plantation in the spinal cord. Histological analysis confirmed that these masses were independent, distant tumors, rather than direct extensions of the main tumor mass, thus demonstrating that the im­planted GBM cells disseminated in the CNS of the zebrafish.45 This is in agreement with our observa­tions of single-cell invasion along the central canal of the spinal cord, which may result in separate tu­mor formation within the spinal cord. The under­lying molecular mechanisms of this rapid invasion remain to be established. The process might be fa­cilitated by the low resistance of the central canal to cell invasion, as the GBM cells are believed to generally invade through structures that have low resistance to cell movement.5,6,46 One of the preferential pathways of GBM inva­sion in the human brain is the white matter, where GBM cells invade along axons.46 It is likely that this preference is recapitulated in zebrafish embryos, as we observed pseudopodal invasion in the midbrain area that is rich in axonal connections between the two hemispheres (Figure 3C). This is reminiscent of tumor invasion via the corpus callosum in human patients.2 Pseudopodia and cell elongation character­ize the mesenchymal type of cell invasion, which is typical for gliomas and depends on cell-matrix adhesion.5,6 The observed strand migration in the spinal cord as well as the midbrain (Figure 2B,4B) is linked to proteolytic matrix remodeling and is characteristic of cancer cells belonging to the mes­enchymal type.5 A mesenchymal molecular finger­print has recently been established for U373 GBM cells.47 This invasion pattern has also previously been observed for U87 cells in mouse models, to­gether with elevated cathepsin B expression at the tumor periphery.48 In a study on zebrafish larvae, invasion of U87 GBM cells along the abluminal sur­face of blood vessels has also been demonstrated.25 As the basal lamina of blood vessels is a known invasion pathway in the human brain46, this fur­ther strengthens the view that the invasion of GBM cells in the zebrafish model resembles this process in mammals. Confocal imaging of GBM and MSC co-cultures in situ revealed that both of these types of cells form mixed tumor masses at similar locations as for the GBM cells alone; i.e., in the ventricles and midbrain hemisphere. The GBM and MSC cells used similar invasion routes along the ventricles and the central canal of the spinal cord, but did not invade other tissues. The association of GBM cells and MSCs into such mixed tumors in the brain of these zebrafish embryos suggests a strong intercellular interaction FIGURE 4. Imaging of co-cultures of GBM cells and MSCs in the brain of zebrafish embryos. A mixture of fluorescent-protein-expressing GBM cells and carbocyanine­dye-labeled MSCs was implanted into the brain of the zebrafish embryos. Three days after implantation, the embryos were fixed, cleared in ScaleU2 without the addition of Triton X-100, and imaged with confocal microscopy. (A) The head of a zebrafish embryo with a co-culture of U87-DsRed cells (red) and DiO-labeled MSCs (green) implanted in the brain. (B) The head of a zebrafish embryo with a co-culture of U373-GFP cells (green) and DiI-labeled MSCs (red) implanted in the brain. (C) Invasion of DiI-labeled MSCs (red) along the central canal of the spinal cord. (D) Three-dimensional rendering of a mixed mass of U373 cells (green) and MSCs (red) in a brain obtained from a cleared embryo. Nuclei are stained with methyl green (presented in blue). Scale bars: 250 µm (A, B); 100 µm (C); 50 µm (D). between them, which would appear to also have a role in the human GBM microenvironment. Indeed, MSC tropism towards GBM cells has previously been described10, and a set of cytokines has been shown to mediate the interactions between these cells in vitro.49,50 Among these, the monocyte che­moattractant protein (MCP-1) has been suggested as the major trigger of various molecular pathways that can enhance MSC proliferation and invasion, whereas a different set of genes has been shown to impair U87 cell invasion and proliferation, and to even induce their senescence.49 When mixtures of U87 or U373 GBM cells and MSCs were implanted FIGURE 5. Fusion between GBM cells and MSCs in the zebrafish brain. A mixture of U373-GFP cells and DiI-labeled MSCs was implanted in the brain of the embryos, which were fixed, cleared and imaged 3 days after implantation of the cells. Two cells (arrows) emit green GFP fluorescence as well as red DiI fluorescence, which strongly indicates that the U373-GFP cells and MSCs have fused after implantation. (A) Nuclei of embryonic tissues labeled with methyl green. (B) Green fluorescent protein fluorescence of U373 cells. (C) Red fluorescence of DiI, used to label the MSCs. (D) Merged image of all of the fluorescent channels. Scale bar: 200 µm. into the zebrafish embryos, these established very close contacts and apparently also formed a struc­tural syncytium in vivo. This finding confirms our previous in-vitro studies of direct co-cultures using U373 GBM cells and MSCs. These studies showed the formation of gap junctions between these cell types (i.e., formation of a functional syncytium), as demonstrated by fluorescein transmission and connexin 43 expression. Furthermore, there was membrane fusion between these cells (i.e., forma­tion of a structural syncytium), as demonstrated by the co-localization of different carbocyanine dyes.15 Direct membrane fusion between the GBM cells and MSCs affects gene expression and the cell phenotype, which might lead to enhanced invasion of hybrid cells, which is of relevance to tumor pro­gression.15 Taken together, our enhanced clearing meth­odology has enabled us to study GBM cell locali­zation in the brain of zebrafish embryos and to observe their interaction with MSCs at single-cell resolution. This allowed us to identify the invasion patterns of GBM cells in the zebrafish brain and identify the central canal of the spinal cord as a ma­jor invasion route. As the frequency of this single-cell invasion of the spinal cord is also quantifiable, the observation of this process in high-throughput screening can now be developed as a fast and objec­tive methodology. Thus it can not only to be used to study basic mechanisms in terms of the differ­ences among heterogeneous GBM populations, but also for diagnostic purposes with patient biopsies. This study is also the first to address co-culture implantation in the zebrafish brain model in order to define the interactions between GBM cells and MSCs. We demonstrated that these two cell types invade the surrounding brain tissue along similar invasion roots as the GBM cells alone, whereby they often moved along the central canal of the spi­nal cord, but did not leave the CNS. In perspective, the zebrafish xenotransplanta­tion model of GBM has many benefits in terms of cost, simplicity, possibility for single-cell visuali­zation in vivo, and high throughput.18 As demon­strated by the present study, this simple model can be used to study cell processes involved in GBM cell invasion and the interactions of GBM cells with many other cells of the stroma in double or triple cell co-cultures. Acknowledgments The authors wish to thank Prof. Dr. Cornelis J.F. van Noorden (Academic Medical Centre, Amsterdam) for his introduction to the CLARITY technique. We also thank Dr. David Dobnik (National Institute of Biology, Ljubljana) for his help with confo­cal microscopy. This work was funded by the INTERREG EC Project 2011, Ref. No. 42 (GLIOMA) and the Reserch Programme P1-0245, awarded by the Slovenian Research Agency. References 1. Ohgaki H, Kleihues P. The definition of primary and secondary glioblastoma. Clin Cancer Res 2013; 19: 764-72. 2. Claes A, Idema A, Wesseling P. Diffuse glioma growth: a guerilla war. Acta Neuropathol 2007; 114: 443-58. 3. Gupta MK, Jayaram S, Reddy DN, Polisetty RV, Sirdeshmukh R. Transcriptomic and proteomic data integration and two-dimensional molecular maps with regulatory and functional linkages: application to cell proliferation and inva­sion networks in glioblastoma. J Proteome Res 2015; 14: 5017-27. 4. 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Received 22 April 2015 Accepted 3 January 2016 Correspondence to: Qingshan You, M.D., Department of Radiation Oncology, The Third Affiliated Hospital of Harbin Medical University, Num.150, Haping Road, Harbin, China, 150081. Phone and Fax: +860 451 8629 8532; E-mail: haveqingsh@163.com Disclosure: No potential conflicts of interest were disclosed. Background. Next generation sequencing and bio-informatic analyses were conducted to investigate the mecha­nism of reactivation of p53 and induction of tumor cell apoptosis (RITA)-enhancing X-ray susceptibility in FaDu cells. Materials and methods. The cDNA was isolated from FaDu cells treated with 0 X-ray, 8 Gy X-ray, or 8 Gy X-ray + RITA. Then, cDNA libraries were created and sequenced using next generation sequencing, and each assay was repeated twice. Subsequently, differentially expressed genes (DEGs) were identified using Cuffdiff in Cufflinks and their functions were predicted by pathway enrichment analyses. Genes that were constantly up- or down-regulated in 8 Gy X-ray-treated FaDu cells and 8 Gy X-ray + RITA-treated FaDu cells were obtained as RITA genes. Afterward, the protein-protein interaction (PPI) relationships were obtained from the STRING database and a PPI network was constructed using Cytoscape. Furthermore, ClueGO was used for pathway enrichment analysis of genes in the PPI network. Results. Total 2,040 and 297 DEGs were identified in FaDu cells treated with 8 Gy X-ray or 8 Gy X-ray + RITA, respec­tively. PARP3 and NEIL1 were enriched in base excision repair, and CDK1 was enriched in p53 signaling pathway. RFC2 and EZH2 were identified as RITA genes. In the PPI network, many interaction relationships were identified (e.g., RFC2-CDK1, EZH2-CDK1 and PARP3-EZH2). ClueGO analysis showed that RFC2 and EZH2 were related to cell cycle. Conclusions. RFC2, EZH2, CDK1, PARP3 and NEIL1 may be associated, and together enhance the susceptibility of FaDu cells treated with RITA to the deleterious effects of X-ray. Key words: hypopharyngeal squamous cell carcinoma; next generation sequencing; RITA; X-ray Introduction Head and neck squamous cell carcinoma (HNSCC), which arises in the head and neck region that composes pharynx, larynx, nasal cavity, oral cavity, paranasal sinuses and sali­vary glands, has an estimated 500,000 new cases and becomes the sixth most common cancer in 2010 worldwide.1 As one type of HNSCC, hy­popharyngeal squamous cell carcinoma (HSCC) has a poor prognosis, and the overall survival rate for HSCC patients is only 15–45%.2,3 The patients diagnosed with HSCC are often at a late stage and distant metastasis occur after conventional treat­ments.2 Thus, the poor survival of patients with HSCC may be due to lacking of early detection and highly metastatic behavior.4 Radiotherapy is the principal treatment of loco-regionally ad­vanced squamous-cell carcinoma of the head and neck region (including oral cavity, oropharynx, hypopharynx, and larynx).5,6 Recently, instead of radiotherapy, chemoradiotherapy has become the standard treatment for patients with locally advanced disease.7 Many small molecules have 169 been identified to enhance the radiation response. For example, panitumumab has been discovered to have an enhanced effect on radiation in the preclinical setting of upper aerodigestive tract cancer.8 Moreover, it has been found that the p53­reactivating small-molecule RITA (reactivation of p53 and induction of tumor cell apoptosis), alone or in combination with cisplatin, can induce the reactivation of p53 in many HNSCC cell lines.9,10 However, this effect is not universal. The HNSCC cell line JHU-028 can express wild type (wt) p53, but the cells do not undergo apoptosis in response to RITA treatment.10 Previously, we used RITA combined with X-ray to investigate the effect of RITA on X-ray suscep­tibility for the treatment of HSCC cell line FaDu (which is HPV-negative cell line) and found that RITA could enhance the radiation response of HSCC (data not shown). In this study, using RNA sequencing data from the HSCC cell line FaDu, we aimed to screen differentially expressed genes (DEGs) between 8 Gy X-ray-treated FaDu cells and 0 Gy X-ray-treated FaDu cells, as well as those be­tween 8 Gy X-ray + RITA treated FaDu cells and 8 Gy X-ray treated FaDu cells. The underlying functions of the DEGs were predicted by Gene Ontology (GO), Kyoto Encyclopedia of Genes and Genomes (KEGG) and BioCarta enrichment analy­sis. Moreover, the genes related to RITA were fur­ther analyzed. Additionally, a protein-protein in­teraction (PPI) network was constructed to identify key genes involved in enhanced X-ray susceptibil­ity of FaDu cells treated with RITA. Materials and methods Cell culture and processing The HSCC cell line FaDu was purchased from American Type Culture Collection (ATCC, Manassas, VA, USA). The FaDu cells were cultured in media made from Dulbecco modified Eagle me­dium (DMEM, GIBCO, Gaithersburg, USA), 10% fetal bovine serum (FBS, GIBCO) and 1% mycil­lin double antibody (GIBCO) at 37°C in a humidi­fied, 5% CO2 incubator (Thermo, Pittsburgh, USA). When the confluency of FaDu cells covered 80%­90% of the petri dish, they were digested with pancreatin (GIBCO), centrifuged, and the super­natant was discarded. Next, the FaDu cells were resuspended in a frozen stock solution composed of 10% dimethyl sulfoxide (DMSO, GIBCO), 40% FBS and 50% DMEM, and preserved in a program frozen box. After digestion, FaDu cells were centrifuged and counted, and then inoculated in 96-well plates (ABI, Foster City, USA) (6×104 cells/well) and cul­tured overnight. Subsequently, RITA (10 mM) (Selleck, Houston, USA) was added to each well of the experimental group, and DMSO (0.1%) was added to that the wells of the control group. The cells were preprocessed for 24 h at 37°C in a hu­midified, 5% CO2 incubator. The plates were then sealed by parafilm and placed in a radiometer, and the cells in the experimental group were irradiated with a radiation dose of 8 Gy and a radiation speed of 1 Gy/min. After irradiation, the parafilm was removed and the plates were placed at 37°C in a humidified, 5% CO2 incubator for 48 h. RNA isolation and sequencing preparation The total RNA was extracted from the cells using the SV total RNA Isolation System (Invitrogen, Shanghai, CHN) according to the manufactur­er’s instructions. The integrity of the total RNA was verified by 2% Agarose Gel Electrophoresis. The purity of RNA was determined by the A260/ A280 ratio as determined by a spectrophotometer (Merinton, Beijing, CHN). Construction of cDNA library The cDNA libraries were constructed using a NEBNext® Ultra™ RNA Library Prep Kit for Illumina® (NEB E7530) (Vazyme, Nanjing, CHN), according to the manufacturer’s instructions. Through heating, mRNA was broken into short fragments (200 nt). Using these short fragments as templates, random hexamer-primer (Sangon, Shanghai, CHN) was used to synthesize the first-strand of cDNA. Next, the second-strand of cD-NA was synthesized. The short fragments were connected to sequencing adapters after poly (A) sequences were added. Afterwards, the UNG en­zyme (Prospect Biosystems, Newark, USA) was used to degrade the second-strand cDNA, and the product was purified using a MiniElute PCR Purification Kit (Qiagen, Dusseldorf, GER) before PCR amplification. Finally, the library could be se­quenced using an Illumina Hiseq 2500 v4 100PE (Illumina, San Diego, USA), and raw reads were generated. Reads with adaptor sequences, with unknown nucleotide content higher than 10% and/or those with low quality bases accounting for higher than 50% of the total nucleotides were filtered out. Sequence alignment and identification of differentially expressed genes The high quality reads were mapped to the human genome (version: hg19) using Tophat (version: 2.0.12), and BAM files were obtained.11 The param­eters were set to defaults. Cuffdiff in Cufflinks12 was used to identify DEGs. The Benjamini & Hochberg method13 was applied to correct for multiple tests. The adjusted p-value (that is false discovery rate, FDR) < 0.05 and |log fold change (FC)| . 1 were used as the cut-off criteria. Functional enrichments The KEGG pathway database can be used to identi­fy the relationships and interactions between genes in a given system.14 KEGG was used for pathway enrichment analysis, and a p-value < 0.05 was con­sidered a significantly enriched pathway. The genes related to RITA (RITA genes) screening To further investigate the effect of RITA on FaDu cells, we identified common DEGs in 0 Gy X-ray treated FaDu cells vs 8 Gy X-ray treated FaDu cells, and 8 Gy X-ray treated FaDu cells vs 8 Gy X-ray + RITA treated FaDu cells (Figure 1). A previous study showed that X-rays could reduce cell viability and that treatment with RITA could enhance the sus­ceptibility of FuDa cells to the deleterious effects of X-rays.10 Therefore, the genes that were consistently up- or down-regulated in 8 Gy X-ray treated FaDu cells vs 0 Gy X-ray treated FaDu cells and 8 Gy X-ray + RITA treated FaDu cells vs 8 Gy X-ray treated FaDu cells were characterized as the RITA genes. PPI network construction The online tool STRING15 was utilized to analyze the interactions between the proteins encoded by the common DEGs. A required confidence (com-bined score) > 0.4 was used as the cut-off criterion. Subsequently, Cytoscape software16 was used to visualize the PPI network. ClueGO analysis ClueGO17 in Cytoscape was used to conduct GO, KEGG and BioCarta enrichment analyses. Further, ClueGO divided terms into different functional groups based on the common genes involved in different terms. In our study, ClueGO was used for KEGG pathway enrichment analysis. A p-value < 0.05 was used as the cut-off criterion. Results Alignment analysis The total reads were above 82% and the mapped reads were above 70% in all of the data sets. The de­tailed sequencing information is shown in Table 1. DEG analysis Compared with 0 Gy X-ray-treated FaDu cells, a total of 2,040 DEGs (1,148 up-regulated and 892 TAblE 1. Summary statistics of paired-end (PE) RNA-Seq reads in six cell lines Sample_L141211001 10467886 8650424 (82.3%) 6846290 (79.1%) 6749179 Sample_L141211002 11510210 9627883 (83.6%) 7197526 (74.7%) 7097908 Sample_L141211003 11119410 9365349 (84.2%) 6910499 (73.7%) 6825529 Sample_L141211004 11271934 9510517 (84.3%) 6752339 (70.9%) 6669811 Sample_L141211005 10854414 9110446 (83.9%) 7129465 (78.2%) 7043831 Sample_L141211006 10532245 8802840 (83.5%) 6752224 (76.7%) 6671073 171 down-regulated DEGs) were identified in the 8 Gy X-ray-treated FaDu cells. Moreover, 297 DEGs (137 up-regulated and 160 down-regulated DEGs) were identified in the 8 Gy X-ray + RITA-treated FaDu cells compared with the 8 Gy X-ray-treated FaDu cells. Pathway enrichment analysis The results of KEGG pathway enrichment for the DEGs are listed in Table 2. Replication factor C sub­unit 2 (RFC2) was significantly enriched in DNA replication (p = 5.85E-19) and nucleotide excision repair (p = 2.25E-04). Poly (ADP-ribose) polymerase 3 (PARP3) and nei endonuclease VIII-like 1 (NEIL1) were significantly enriched in the pathway of base excision repair (p = 2.00E-08). Moreover, cyclin-de­pendent kinase 1 (CDK1) was significantly enriched in the p53 signaling pathway (p = 1.85E-02). RITA genes screening A total of 20 consistently dysregulated genes in the 8 Gy X-ray-treated FaDu cells vs 0 Gy X-ray- TAblE 2. The top ten up- and down-regulated DEGs between 0 GY X-ray treated FaDu cells and 8 GY X-ray treated FaDu cells, as well as 8 GY X-ray treated FaDu cells and 8 GY X-ray + RITA treated FaDu cells BMF -1.79769e+308 1.23E-11 BMF -1.79769e+308 1.23E-11 SDCBP -1.79769e+308 0.00097112 SDCBP -1.79769e+308 0.00097112 IL32 -1.79769e+308 0.0110064 IL32 -1.79769e+308 0.0110064 MAD1L1 -1.79769e+308 9.77E-05 MAD1L1 -1.79769e+308 9.77E-05 SIRT3 -1.79769e+308 0.00289562 SIRT3 -1.79769e+308 0.00289562 Up-regulated KAZN -1.79769e+308 7.93E-10 KAZN -1.79769e+308 7.93E-10 TSPAN4 -1.79769e+308 0.0136997 TSPAN4 -1.79769e+308 0.0136997 PPAN-P2RY11 -1.79769e+308 4.71E-08 PPAN-P2RY11 -1.79769e+308 4.71E-08 CDC14B -1.79769e+308 1.49E-06 CDC14B -1.79769e+308 1.49E-06 CXCL16 -1.79769e+308 0.000434357 CXCL16 -1.79769e+308 0.000434357 C3orf14 -5.88442 0.006353 KCTD2 -3.8901 1.23E-06 TTC28-AS1 -3.10554 1.30E-09 TSPAN4 -3.68234 0.0124825 KRT4 -2.86398 0 FGFR3 -3.47603 0.0322468 ALPP -2.68741 1.30E-13 PLEKHM1.1 -3.41618 0.0191408 MND1 -2.64752 0.022297 CHFR -3.39824 0.0369514 Down-regulated DHRS2 -2.38983 4.17E-11 KREMEN2 -3.32824 0.033903 FGF3 -2.33156 2.25E-12 SMAP2 -3.3199 0.0215792 TERC -2.268 0.027132 EPS15L1 -3.30518 0.00562372 UTP20 -2.23728 0 MORF4L2 -3.0731 0.0300806 GAL -2.22661 0 PIGQ -2.94079 0.0327601 DEGs = differentially expressed genes treated FaDu cells and in the 8 Gy X-ray + RITA-treated FaDu cells vs 8 Gy X-ray-treated FaDu cells were identified, including 13 consistently up-regulated (B cell lymphomas 6, BCL6; integrin, beta 2-antisense RNA 1, ITGB2-AS1; L1 cell ad­hesion molecule, L1CAM; LIM and calponin ho­mology domains 1, LIMCH1; latent transforming growth factor-ß binding protein 3, LTBP3; v-MAF avian musculoaponeurotic fibrosarcoma onco­gene family, MAFF; neutrophil cytosolic factor 2, NCF2; nuclear factor of activated T-cells, cytoplas­mic, calcineurin-dependent 1, NFATC1; PARP3; RAB43, member RAS oncogene family, RAB43; regulator of cell cycle, RGCC; Src homology 2 do­main containing F, SHF; and troponin T type 1, TNNT1) and 7 consistently down-regulated DEGs (adenylosuccinate lyase, ADSL; enhancer of zeste homolog 2, EZH2; nudix-type motif 1, NUDT1; proteasome 26S subunit, non-ATPase 11, PSMD11; RFC2; Treacher Collins-Franceschetti syndrome 1, TCOF1; and X-ray repair cross-complementing group 3, XRCC3) (Figure 1). PPI network and module analysis The PPI network for RITA genes and the DEGs related to RITA had 448 interactions (Figure 2). In the PPI network, the RITA genes of RFC2 (degree = 126) and EZH2 (degree = 115) had relatively higher degrees. Additionally, RFC2 and EZH2 could inter­act with CDK1. The results of the pathway enrich­ment analysis for RFC2, EZH2 and their interaction genes are shown in Figure 3. RFC2 and EZH2 were enriched in the cell cycle pathways, oocyte meiosis, and DNA replication. Discussion In the present study, a total of 2,040 DEGs, includ­ing 1,148 up-regulated and 892 down-regulated DEGs, were identified in 8 Gy X-ray-treated FaDu cells, compared with 0 Gy X-ray-treated FaDu cells. Moreover, 297 DEGs, including 137 up-regulated and 160 down-regulated DEGs, were identified in 8 Gy X-ray + RITA-treated FaDu cells, compared with 8 Gy X-ray-treated FaDu cells. Among these DEGs, EZH2 and RFC2, which were consistently down-regulated in 8 Gy X-ray-treated FaDu cells vs 0 Gy X-ray-treated FaDu cells and 8 Gy X-ray + RITA-treated FaDu cells vs 8 Gy X-ray-treated FaDu cells, were characterized as the RITA genes. A previous study has reported that enhancers of EZH2, which is the enzymatic component of the polycomb repressive complex 2, can regulate cell proliferation and differentiation during embryonic development.18 Moreover, it has also been demon­strated that targeting EZH2 can suppress cancer progression and recurrence by reversing oncogen­ic properties and stemness of tumor cells.19 RFC2, belonging to the replication factor C family, has been implicated in nasopharyngeal carcinoma.20 In our study, ClueGO analysis showed that RFC2 and EZH2 were related to the cell cycle. Cell cycle regulation by p53 is widely accepted as the major mechanism for tumor formation.21 Therefore, we speculated that RFC2 and EZH2 may regulate the cancer cell proliferation of HSCC cells through the cell cycle pathway. According to the PPI network, both RFC2 and EZH2 could interact with CDK1, and the KEGG pathway enrichments showed that CDK1 was significantly enriched in the p53 sign­ 173 TAblE 3. The KEGG pathway enrichment for the DEGs between 0 GY X-ray treated FaDu cells and 8 GY X-ray treated FaDu cells, as well as 8 GY X-ray treated FaDu cells and 8 GY X-ray + RITA treated FaDu cells. gy8ctl vs. gy0ctl hsa03030: DNA replication 28 5.85E-19 POLA1, POLA2, RPA3, RPA1, PRIM1, RPA2, POLE4, MCM7, POLE3, FEN1 hsa04110: Cell cycle 43 1.91E-11 E2F1, E2F2, DBF4, PRKDC, PKMYT1, CHEK1, CDC45, MCM7, CDKN2B, CDKN2C … hsa03430: Mismatch repair 16 1.15E-09 EXO1, SSBP1, MSH2, LIG1, MLH1, RPA3, RFC5, POLD3, RPA1, RPA2 … hsa00240: Pyrimidine metabolism 32 2.00E-08 POLR2G, DTYMK, POLA1, CAD, POLA2, CMPK2, TK1, PRIM1, TYMS, POLE4 … hsa03410: Base excision repair 16 2.06E-06 HMGB1, UNG, NEIL3, LIG1, POLE, NEIL1, POLD3, POLD4, POLE4, POLE3 … hsa03440: Homologous recombination 14 3.36E-06 RAD51C, XRCC3, NBN, BLM, SSBP1, MRE11A, EME1, RPA3, RAD51, POLD3 … hsa03420: Nucleotide excision repair 15 2.25E-04 LIG1, POLE, RPA3, RFC5, POLD3, RPA1, RPA2, POLD4, RFC3, POLE4 … hsa00230: Purine metabolism 33 3.73E-04 XDH, POLR2G, POLA1, POLA2, PFAS, PRIM1, POLE4, POLE3, PDE4A, ENTPD8 … hsa05200: Pathways in cancer 52 0.010417112 FGF19, E2F1, HSP90AB1, E2F2, PTGS2, PDGFB, PGF, STAT5A, ARNT2, FGF11 … hsa05219: Bladder cancer 11 0.016627297 E2F1, E2F2, TYMP, CDKN1A, PGF, VEGFA, RB1, DAPK2, CDK4, MMP2, DAPK1 hsa04115: p53 signaling pathway 15 0.018499656 CDK1, CYCS, CHEK1, ATR, CDK4, CCNG2, GTSE1, CCNB1, CDKN1A, CCNB2 … hsa04512: ECM-receptor interaction 17 0.024887625 HSPG2, SDC4, COL5A1, CHAD, HMMR, VWF, LAMB3, LAMB2, ITGB8, ITGA5 … hsa03020: RNA polymerase 8 0.03298698 POLR3G, POLR2G, POLR3K, POLR1E, POLR1A, POLR1C, POLR1B, POLR3B hsa00970: Aminoacyl-tRNA biosynthesis 10 0.036943456 IARS, NARS2, LARS, FARSB, EPRS, WARS2, DARS2, AARS2, KARS, EARS2 hsa03040: Spliceosome 22 0.044130211 NCBP1, MAGOH, TRA2B, LSM6, TRA2A, SNRPD1, HSPA1A, PRPF4, RBMX, HNRNPA1 … hsa05222: Small cell lung cancer 16 0.048720159 E2F1, TRAF1, E2F2, CKS1B, PTGS2, PIK3CD, CYCS, SKP2, RB1, BIRC3 … gy8rita vs. gy8ctl hsa03410: Base excision repair 4 0.014381142 NEIL1, LIG3, PARP3, SMUG1 hsa05212: Pancreatic cancer 5 0.021107952 AKT1, PGF, PIK3CB, ERBB2, RALGDS hsa05213: Endometrial cancer 4 0.040674333 AKT1, PIK3CB, ERBB2, CTNNA1 hsa04150: mTOR signaling pathway 4 0.040674333 AKT1, PGF, PIK3CB, EIF4E2 DEGs = differentially expressed genes aling pathway. p53 can negatively regulate the transcription of a large number of genes (includ­ing BCL-2 and MCL1) that suppress apoptosis.22 Additionally, a former study has also demonstrat­ed that the reactivation of p53 can induce apoptosis in HNSCC, which includes HSCC.23 Consequently, we proposed that CDK1 could be correlated with HSCC by regulation of apoptosis of the cancer cells through the p53 signaling pathway. In addition, CDK1 might also function in HSCC through inter­acting with RFC2 and EZH2. Additionally, the RITA gene PARP3 was sig­nificantly enriched in base excision repair. Base excision repair is a cellular mechanism that repairs damaged DNA throughout the cell cycle. It has been reported that the DNA repair capacity is cru­cial for preventing genomic instability and, in turn, may be associated with heightened risk of can­cer.24 Furthermore, reduced expression of nucleo­tide excision repair core genes such as Cockayne’s syndrome complementary group B/excision repair cross-complementing 6 (CSB/ERCC6), excision re­pair cross-complementing 1 (ERCC1), Xeroderma pigmentosum group G/excision repair cross-com­plementing 5 (XPG/ERCC5) and Xeroderma pig­mentosum group B/excision repair cross-comple­menting 3 (XPB/ERCC3) can increase the risk for development of HNSCC for more than two-fold.25 The ADP ribosyl transferase PARP3 gene has been identified as a vital player in the stabilization of mi­totic spindles and in telomere integrity. Notably, PARP3 associates and regulates the mitotic com­ponents NuMA and tankyrase 1; therefore, PARP3 can be a potential biomarker in cancer therapy.26 In the PPI network, PARP3 is capable of interacting with EZH2. Accordingly, it came to the speculation that PARP3, as well as its interaction with EZH2, could play a role in HSCC by regulating DNA damage through the base excision repair pathway. Moreover, NEIL1 was also enriched in base exci­ 174 sion repair. A former study showed that the func­tional variants of the NEIL1 protein can lead to risk and progression of squamous cell carcinomas of the oral cavity and oropharynx.27 Therefore, PARP3 and NEIL1 could be involved in development of HSCC through the base excision repair pathway. RFC2, EZH2, CDK1, PARP3 and NEIL1 may be related to an enhancement of the susceptibility of FaDu cells to X-rays with co-treatment of RITA. However, further research is needed to illustrate their mechanisms. References 1. Torre LA, Bray F, Siegel RL, Ferlay J, Lortet-Tieulent J, Jemal A. Global cancer statistics, 2012. CA Cancer J Clin 2015; 65: 87-108. 2. Chaturvedi AK, Engels EA, Pfeiffer RM, Hernandez BY, Xiao W, Kim E, et al. Human papillomavirus and rising oropharyngeal cancer incidence in the United States. J Clin Oncol 2011; 29: 4294-301. 3. Van Monsjou HS, Balm AJ, Van den Brekel MM, Wreesmann VB. Oropharyngeal squamous cell carcinoma: a unique disease on the rise? Oral Oncol 2010; 46: 780-5. 4. Garden AS, Asper JA, Morrison WH, Schechter NR, Glisson BS, Kies MS, et al. Is concurrent chemoradiation the treatment of choice for all patients with Stage III or IV head and neck carcinoma? Cancer 2004; 100: 1171-8. 5. Kramer S, Gelber RD, Snow JB, Marcial VA, Lowry LD, Davis LW, et al. Combined radiation therapy and surgery in the management of advanced head and neck cancer: final report of study 73–03 of the Radiation Therapy Oncology Group. Head Neck Surg 1987; 10: 19-30. 6. Kato K, Muro K, Minashi K, Ohtsu A, Ishikura S, Boku N, et al. Phase II study of chemoradiotherapy with 5-fluorouracil and cisplatin for stage II–III esophageal squamous cell carcinoma: JCOG Trial (JCOG 9906). Int J Radiat Oncol Biol Phys 2011; 81: 684-90. 7. Kruser TJ, Armstrong EA, Ghia AJ, Huang S, Wheeler DL, Radinsky R, et al. Augmentation of radiation response by panitumumab in models of upper aerodigestive tract cancer. Int J Radiat Oncol Biol Phys 2008; 72: 534-42. 8. Roh J-L, Ko JH, Moon SJ, Ryu CH, Choi JY, Koch WM. The p53-reactivating small-molecule RITA enhances cisplatin-induced cytotoxicity and apoptosis in head and neck cancer. Cancer Lett 2012; 325: 35-41. 9. Roh J-L, Kang SK, Minn I, Califano JA, Sidransky D, Koch WM. p53-Reacti­vating small molecules induce apoptosis and enhance chemotherapeutic cytotoxicity in head and neck squamous cell carcinoma. Oral Oncol 2011; 47: 8-15. 10. Kim D, Pertea G, Trapnell C, Pimentel H, Kelley R, Salzberg SL. TopHat2: ac­curate alignment of transcriptomes in the presence of insertions, deletions and gene fusions. Genome Biol 2013; 14: R36. 11. Trapnell C, Williams BA, Pertea G, Mortazavi A, Kwan G, van Baren MJ, et al. Transcript assembly and quantification by RNA-Seq reveals unannotated transcripts and isoform switching during cell differentiation. Nat Biotechnol 2010; 28: 511-15. 12. Benjamini Y, Hochberg Y. Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc Series B Stat Methodol 1995; 57: 289-300. 13. Kanehisa M, Goto S. KEGG: kyoto encyclopedia of genes and genomes. Nucleic Acids Res 2000; 28: 27-30. 14. Franceschini A, Szklarczyk D, Frankild S, Kuhn M, Simonovic M, Roth A, et al. STRING v9. 1: protein-protein interaction networks, with increased coverage and integration. Nucleic Acids Res 2013; 41: D808-D15. 15. Saito R, Smoot ME, Ono K, Ruscheinski J, Wang P-L, Lotia S, et al. A travel guide to Cytoscape plugins. Nat Methods 2012; 9: 1069-76. 16. Bindea G, Mlecnik B, Hackl H, Charoentong P, Tosolini M, Kirilovsky A, et al. ClueGO: a Cytoscape plug-in to decipher functionally grouped gene ontol­ogy and pathway annotation networks. Bioinformatics 2009; 25: 1091-93. 17. Qi W, Chan H, Teng L, Li L, Chuai S, Zhang R et al. Selective inhibition of Ezh2 by a small molecule inhibitor blocks tumor cells proliferation. Proc Natl Acad Sci 2012; 109: 21360-65. 18. Chang C, Hung M. The role of EZH2 in tumour progression. Br J Cancer 2012; 106: 243-47. 19. Xiong S, Wang Q , Zheng L, Gao F, Li J. Identification of candidate molecular markers of nasopharyngeal carcinoma by tissue microarray and in situ hy­bridization. Med Oncol 2011; 28: 341-48. 20. Li T, Kon N, Jiang L, Tan M, Ludwig T, Zhao Y, et al. Tumor suppression in the absence of p53-mediated cell-cycle arrest, apoptosis, and senescence. Cell 2012; 149: 1269-83. 21. Mirzayans R, Andrais B, Scott A, Murray D. New insights into p53 signaling and cancer cell response to DNA damage: implications for cancer therapy. Biomed Res Int 2012: 170325. doi: 10.1155/2012/170325. 22. Chuang H-C, Yang LP, Fitzgerald AL, Osman A, Woo SH, Myers JN, et al. The p53-Reactivating Small Molecule RITA Induces Senescence in Head and Neck Cancer Cells. PLoS One 2014; 9: e104821. 23. de Boer JG. Polymorphisms in DNA repair and environmental interactions. Mutat Res 2002; 509: 201-10. 24. Song X, Sturgis EM, Jin L, Wang Z, Wei Q , Li G. Variants in nucleotide exci­sion repair core genes and susceptibility to recurrence of squamous cell carcinoma of the oropharynx. Int J Cancer 2013; 133: 695-704. 25. Boehler C, Gauthier LR, Mortusewicz O, Biard DS, Saliou J-M, Bresson A, et al. Poly (ADP-ribose) polymerase 3 (PARP3), a newcomer in cellular response to DNA damage and mitotic progression. Proc Natl Acad Sci 2011; 108: 2783-88. 26. Zhai X, Zhao H, Liu Z, Wang L-E, El-Naggar AK, Sturgis EM, et al. Functional variants of the NEIL1 and NEIL2 genes and risk and progression of squamous cell carcinoma of the oral cavity and oropharynx. Clin Cancer Res 2008; 14: 4345-52. 175 research article Diffusion tensor MR microscopy of tissues with low diffusional anisotropy Franci Bajd1,2, Carlos Mattea1, Siegfried Stapf1, Igor Sersa2 1 TU Ilmenau, Institute of Physics, Fachgebiet Technische Physik II, Ilmenau, Germany 2 Jožef Stefan Institute, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 175-187. Received 27 August 2015 Accepted 8 February 2016 Correspondence to: Igor Serša, Ph.D., Jožef Stefan Institute, Jamova 39, SI-1000 Ljubljana, Slovenia. Fax: + 386 1 477 3191; E-mail: igor.sersa@ijs.si Disclosure: No potential conflicts of interest were disclosed. Background. Diffusion tensor imaging exploits preferential diffusional motion of water molecules residing within tissue compartments for assessment of tissue structural anisotropy. However, instrumentation and post-processing errors play an important role in determination of diffusion tensor elements. In the study, several experimental factors affecting accuracy of diffusion tensor determination were analyzed. Materials and methods. Effects of signal-to-noise ratio and configuration of the applied diffusion-sensitizing gradi­ents on fractional anisotropy bias were analyzed by means of numerical simulations. In addition, diffusion tensor mag­netic resonance microscopy experiments were performed on a tap water phantom and bovine articular cartilage-on-bone samples to verify the simulation results. Results. In both, the simulations and the experiments, the multivariate linear regression of the diffusion-tensor analysis yielded overestimated fractional anisotropy with low SNRs and with low numbers of applied diffusion-sensitizing gra­dients. Conclusions. An increase of the apparent fractional anisotropy due to unfavorable experimental conditions can be overcome by applying a larger number of diffusion sensitizing gradients with small values of the condition number of the transformation matrix. This is in particular relevant in magnetic resonance microscopy, where imaging gradients are high and the signal-to-noise ratio is low. Key words: microscopy; diffusion tensor imaging; anisotropy; signal-to-noise ratio; cartilage Introduction Diffusion tensor imaging (DTI) is a widely used magnetic-resonance imaging (MRI) technique, which enables noninvasive assessment of struc­tural integrity of fibrous tissues with a high de­gree of anisotropy, such as brain white matter and myocardium.1,2 Specifically, the technique could be exploited for a dynamical follow-up of minor anisotropy alternations due to tissue structural changes arising during progressive disease devel­opment, such as schizophrenia3, multiple sclerosis4 and myocardium infarct.5 The method is gaining clinical interest also in applications to tissues with less expressive anisotropy or highly localized com­partments with increased level of fiber alignment, such as articular cartilage6,7, which is a relatively thin tissue with a thickness of up to few millim­eters and has a depth-dependent collagen fiber architecture. In DTI, the basic assumption is that diffusive motion of spin bearing particles within the tissue is determined by an alignment of tissue fibers; hence their diffusional anisotropy directly corresponds to anisotropy of the restrictive fibers. The method basically consists of an imaging part, usually employing spin-echo based MRI pulse sequences8, to which a pair of diffusion sensitiz­ing gradients (DSG) is added in order to encode magnetic resonance (MR) signal of spin bearing particles with diffusive motion, resulting into a diffusion-attenuated MR signal. In order to obtain sufficient information on anisotropy of diffusive motion, DSG must be applied in at least six non-coplanar directions to determine six independent elements of the laboratory-frame diffusion tensor.9 In the DT-MRI analysis, diffusion anisotropy is cal­culated by transforming the laboratory-frame dif­fusion tensor into the principal frame of reference using diagonalization.10 Determination of diffusion anisotropy can be bi­ased due to instrumentation imperfections9, such as non-optimally calibrated DSG, and due to post­processing errors.11,12 It was shown, that a number and directionality of the applied DSG configuration play an important role in a noise propagation in DTI post-processing analysis.12 Specifically, noise propagation in DTI, resulting to noise-induced rotational variance of diffusion tensor ellipsoid, can be reduced by decreasing a condition number ( ) of the b-matrix12 as well as by increasing the signal-to-noise ratio ( ).11 Therefore, attempts were made to find a robust measure for diffusion anisotropy, such as the lattice index.13 Among all the proposed measures fractional anisotropy (FA) became commonly accepted. Accuracy in determi­nation of diffusion tensor is of a great importance in biomedical imaging as falsely measured tissue anisotropy could lead to clinical misinterpretations and inappropriate treatment decisions.14 Reliability of the DTI method can be efficiently tested either by using perfectly aligned fiber phan­toms with an a priori known anisotropy, yielding anisotropic diffusion along the preferential fiber orientation15,16, or by using completely isotropic materials. In both cases, overestimated apparent anisotropy could arise as an undesirable conse­quence of the DTI analysis. A fundamental ques­tion is, how the DTI factors, specifically and a choice of a DSG configuration, influence accuracy of a diffusion tensor determination. This issue is specifically important in diffusion tensor magnetic resonance microscopy (DT-MRM), in which is usually low due a high diffusion weighting and due to a small voxel size, respectively. The effect of low SNR is more pronounced in some biomaterials with anisotropic diffusion that exhibit short T2 re­laxation time, as for example articular cartilage.17,18 The main motivation for this study is analysis of factors influencing diffusion anisotropy in DT­MRM signal post-processing. The study is organ­ized into two parts. In the first part, the effect of noise propagation from synthetic raw DTI data to the diffusion tensor eigenvalues is examined theoretically for different DSG configurations: se­lected commonly used, random and isotropic DSG configurations. In the second part, the theoretical results are verified experimentally. DT-MRM was performed for two different materials, tap wa­ter with isotropic diffusion and bovine articular cartilage-on-bone samples before and after com­pression. The study is in particular focused to un­favorable experimental conditions that often arise in DT-MRM and could result in biased diffusional anisotropy. Materials and methods Theoretical background and simulations Single-voxel DTI data of an isotropic medium with a diffusion constant equal to were generated as a -dimensional column vector ( being the number of DSG directions) containing normalized magnitude MR signal intensities [1] where is referred to as dif­ fusion attenuation 19 and is a noise factor. Here, is gyromagnetic ratio, is DSG amplitude, is duration of an individual DSG pulse, is time-separation between the two DSG pulses and is signal-to-noise ratio in the pulsed field gradient (PFG) pulse sequence. The noise was introduced to the generated DTI data by a -dimensional noise vector , of which com­ponents are uniformly distributed ran­dom numbers, which are included in the noise fac­tor. Seventeen commonly used DSG directions12, presented in Table 1, as well as different random and isotropic DSG directions with were considered. With random DSG configura­tions, directions of diffusion sensitizing gradients were modeled as [2] where are three evenly distributed random numbers with . Isotropic DSG configurations were obtained from the corresponding random DSG configurations (for each ) by numerically minimizing their average Coulomb-like interaction energy (i.e., the Thompson’s problem20) , [3] 177 using Monte Carlo simulation approach.21 For each DSG, its transformation matrix was calculated using definition [4] where [5] and the effective gradient for a spin echo-like DTI pulse sequence including a pair of DSG gradients is equal to [6] The 3 x 3 b-value matrix defined in Eq. 4 has only six different elements that can be ar­ranged into a 1 x 6 raw vector with elements . The raw vec­tors can be further arranged into a x 6 DTI transformation matrix . A condition number of the matrix was calculated as . The components of the diffusion tensor in the laboratory frame of reference, , were calculated by solving an over-determined system of equations, , in a form of [7] The laboratory-frame diffusion tensor, [8] was then diagonalized to the principal-axis-frame diffusion tensor [9] TABLE 1. A list of the analyzed commonly used diffusion sensitizing gradients (DSG) configurations in DTI, adopted from12, along with the corresponding values of , and . 1 Tetrahedral 6 9.148 16.53 2 Cond 6 6 5.984 14.19 3 Decahedral 10 2.748 10.70 4 Jones noniso 7 2.560 12.13 5 Dual-gradient 6 2.000 11.44 6 Jones 10 10 1.624 9.67 7 Jones 20 20 1.615 8.10 8 Jones 30 30 1.594 7.16 9 Papadakis 12 1.587 9.29 10 Jones 6 6 1.583 11.04 11 Muthupallai 6 1.581 11.11 12 Tetraortho 7 1.527 10.68 13 DSM 6 6 1.323 11.41 14 DSM 10 10 1.324 10.02 15 DSM 20 20 1.668 8.43 16 DSM 30 30 1.430 7.45 17 DSM 40 40 1.401 6.87 CN = ondition number the corresponding and were calculated as a function of ( ) and ( ) for different noise vectors mimicking different experiments of which results were then averaged in order to reduce their randomness: [11] The diffusion tensor eigenvalues , and were used to calculate the average diffusion coeffi­ cient, , and the fractional anisotropy, defined as10 [10] For each DSG configuration, either taken from the Table 112 or calculated as random or isotropic directions, diffusion tensor eigenvalues as well as The diffusion tensor quantities were then av­eraged over the characteristic window of the domain ( ) to obtain their representative characteristic scalar val­ues denoted as and . For random DSG configurations, a relation between and was modeled with a power-law function [12] where and are two fitting parameters. In the simulations, water-like isotropic medium with was considered. Simulations were performed using an in-house written program, developed within the Matlab pro­gramming environment (MathWorks Inc., Natick, MA, USA). Flowcharts presenting the simulation algorithm for the simulations including DSG con­figurations from Table 1 and random or isotropic DSG configurations are shown in Figure 1. Additional numerical simulations were per­formed in order to investigate the effect of noise propagation in tissues with low diffusional ani­sotropy. In these simulations, diffusion tensor in the principal frame of reference was considered as a prolate spheroid, which was, for the sake of convenience, oriented with the largest dimension along the z-axis of the laboratory frame of refer­ence (zLAB). In this direction, non-restricted diffu­sion was assumed, i.e., the corresponding eigen­value was equal to D0, while diffusion was reduced to .D0 (0 . . . 1) in the other two orthogonal di­rections. The principal-frame diffusion tensor was hence modeled as [13] The primary eigenvector (corresponding to the largest eigenvalue) was equal to , while the other two eigenvectors were chosen as and . The eigenvec­ 179 tors determined the change-of-basis transforma­tion matrix between the principal and the labora­tory frame of reference: . [14] The transformation of the diffusion tensor into the laboratory frame of reference was calculated as . In the case of the above-defined prolate spheroid, components of the dif­fusion tensor in the laboratory frame of refer­ ence were expressed by where . Normally distributed (Gaussian) noise was added to the MR signal intensities. For a given preset FA value and for a given DSG con­figuration, the results of simulations are presented by a difference between the calculated fractional anisotropy FA’ and the preset fractional anisotropy FA, i.e., by . In addition, an orientation dif­ference between the preset and the calculated pri­ mary eigenvector, i.e., , is pre­sented as well. DT-MRM of tap water DT-MRM experiments of a tap water phantom with a cone shape were performed on a horizon-tal-bore 2.35-T MRI scanner (Oxford Instruments, Abingdon, United Kingdom), equipped with microimaging accessories (Bruker, Ettlingen, Germany) and controlled by a Tecmag Apollo spectrometer (Tecmag, Houston TX, USA). The gradient system had top gradients of 0.25 T/m and slew rate of 1200 mT/m/ms. For acquisition of one-dimensional DTI profiles along cone axis, a spin-echo based 1D DT-MRM sequence was employed. For the sequence, the following imaging param­eters were used: 256 acquisition points, field of view 40 mm, spatial resolution of 156 µm, dwell time 10 µs, number of averages 4 (with the half-Cy­clops phase cycling scheme), echo and repetition time . Square-shaped DSG pulses with and were used, yielding the corresponding diffusion attenuation equal to . 1D DT-MRM was examined for isotropic DSG configurations with . The contribution of imaging gradients to the DTI transformation matrix was minimized using non-selective (hard) excitation RF pulses and by performing imaging in just one dimension. As the read gradients in 1D DT-MRM were applied only during or close to MR signal ac­quisition, their contribution to the transformation matrix was minor and was therefore neglected. Prior to the experiments, Stejskal-Tanner plots were measured for each gradient channel. The gra­dient channels were then calibrated to yield a dif­fusion constant of water at room temperature. DT-MRM of articular cartilage Bovine cartilage-on-bone samples, containing an intact cartilage tissue and the underlying part of a subchondral bone, were carefully dissected from fresh stifle joints of bovine femur bones (pro­vided by a local meat provider ) using a commer­cially available bow saw and a dentist driller set (Meisinger, Neuss, Germany). Samples were cut into cylindrically shaped pieces with a diameter of 6 mm and with an average height of 8 mm, fit­ting to an NMR tube with an inner diameter of 7 mm. After dissection, the samples were washed in physiological phosphate buffer saline (PBS) and sealed into plastic bags for deep-freezing storage.22 Prior to DT-MRM experiments, each sample was allowed to spontaneously defreeze at temperature of 8°C. Then, the sample was inserted into an NMR tube and immersed into Fluorinert FC-70 (Sigma-Aldrich, Germany), which was used to prevent samples from desiccation. Compression of articu­lar cartilage was obtained by loading a plastic in­denter, positioned above the articular surface, with weight-induced pressure of at the in­denter-cartilage interface. After the application of an external pressure, each sample was allowed for spontaneous equilibration for 2 hours.17 DT-MRM experiments on articular cartilage-on­bone samples were performed on a 7-Tesla verti­cal-bore superconducting magnet equipped with microimaging accessories and controlled by the Avance spectrometer (Bruker, Ettlingen, Germany). The gradient system had maximum gradients of 1 T/m and slew rate of 4000 mT/m/ms. Due to rela­tively fast transversal relaxation processes in carti­lage tissue, DT-MRM was performed using a stim­ulated-echo pulse sequence. The following imaging parameters were used: imaging matrix 256 x 128 (or 128 x 64), field of view 20 x 10 mm, isotropic in-plane resolution of 78 um (or 156 um), slice thickness 2 mm, dwell time 10 µs (or 20 µs), number of averages yielding the corresponding diffusion attenuation equal to 32, echo and repetition time . A DSG configuration with and was used.18 Square-shaped DSG pulses with and were used, . Again, the imaging gradients (read-dephase and phase gradients) were applied immediately before MR signal acquisition in order to minimize their contribution to the transformation matrix . All gradients, the imaging gradients and DSG, were considered in the numerical calculation of the transformation matrix elements (according to Eq. 4). All DT-MRM analyses were performed with­in the Matlab programming environment. Results Simulated 2D maps over the domain of the second largest eigenvalue , of the 181 difference among the smallest and the largest ei­genvalue and of the corresponding fractional anisotropy for four representative DSG configurations, i.e., the DSG configurations #1, #8, #13 and #16 from Table 1, are presented in Figure 2. Two of the selected DSG configurations correspond to the commonly used DSG configurations (#1 with and #8 with in Figure 3A,B, respectively), while the other two correspond to the DSG configurations, optimized in12 with respect to the condition num­ber (again with and ). It can be seen that the largest deviations of the studied diffusion tensor quantities from their ideal values ( from , from 0 and from 0) are found at high values of and low values of . From the result in Table 1, it is evident that region pro­portions of poorly determined DT eigenvalues, i.e., dark red regions in maps in Figure 2 defined by the condition de­crease with a decreasing . The results in Table 1 also indicate that for all DSG configurations, the proportion could be additionally decreased by increasing . Figure 3 shows domain-averaged val­ues of diffusion tensor eigenvalues , and (Figure 3A,B) along with the corresponding aver­age diffusion coefficient (Figure 3C,D) and fractional anisotropy (Figure 3E,F) as a function of for random DSG configurations with differ­ent . The results are shown in two formats, i.e., the cal­culated quantities in a log format with a broad range of condition numbers are shown in Figure 3A,C,E, while the same quantities in a lin­ear format with the range of (zoomed gray regions of the corresponding log graphs) are shown in Figure 3B,D,F. From the graphs in Figure 4 it can be seen that random DSG configura­tions with low and high overestimate the largest diffusion tensor eigenvalue and underes­timate the smallest eigenvalue, while the remain­ing eigenvalue remains independent on and the equality holds for a broad range of . Therefore, the difference remains non-zero (of the order of ) also for the smallest values. Interestingly, as the difference is symmet­ric with respect to , its undesired contribution is canceled in the calculation of , of which val­ues are hence only weakly scattered around in a broad range of . On the contrary, the symmetric difference is not canceled in the calculation of , which thus contributes to an existence of the apparent fractional anisotropy of a generic iso- FIGURE 3. Panels on the left show simulated average values of diffusion tensor eigenvalues , and (A), of average diffusion constant (C) and of fractional anisotropy (E) as a function of condition number for random diffusion sensitizing gradients (DSG) configurations. Panels on the right (B,D,F) display the zoomed left-side panels for condition numbers in the range . Solid-line curves (E,F) correspond to best fits of the model function [Eq. 12] to the simulated data. The graphical insert in panel (A) illustrates the selected random DSG configuration with . tropic medium. With in the range of , the values of span range between 0.01 and 0.08. In Figure 4, the minimal was obtained with . Clearly, apparent fractional anisot­ropy is highly dependent on the condition number. Solid curves in Figure 3E,F represent best fits of the model function in Eq. 12 to the simulated vs. data calculated for each independently. As can be seen from the graphs in Figure 3E,F, the model fits well to the data for , while for the model is less accurate due to satura­tion of . Figure 4 shows maximal, average and minimal values of (Figure 4A) as well as the optimally fitting parameters of Eq. 12, i.e., and , along FIGURE 4. Characteristic values of the simulated correlations between and for random diffusion sensitizing gradients (DSG) configurations as a function of : maximal, average and minimal values of (A), best fit parameters , and fit quality (B). The arrow designates a crossover, at which apparent fractional anisotropy drops below fractional anisotropy . The graphical insert in panel A illustrates the selected random DSG configuration with . FIGURE 5. Simulated average fractional anisotropy (solid symbols) and the corresponding condition number (void symbols) as a function of for random (blue symbols) and isotropic (red symbols) diffusion sensitizing gradients (DSG) configurations. The graphical insert illustrates a distribution of DSG directions in a random and an isotropic DSG configuration with . with the corresponding values of as a function of for random DSG directions (Figure 4B). The data shown in Figure 4 are taken from Figure 3E,F. From Figure 4A it can be seen that the maximal and minimal as well as the difference between them decrease with an increasing . At , both, the maximal and minimal drop to ap­proximately 0.01. In addition, as can be seen from Figure 4B, best fit parameters are monotonically decreasing for . However, fit quality de­ creases with larger from at to at . Average fractional anisotropy (solid sym­bols) and the corresponding condition number (void symbols) as a function of , for both random (blue symbols) and the corresponding isotropic (red symbols) DSG configurations, are shown in Figure 5. The data shown in Figure 5 were obtained by averaging the corresponding quantities that were calculated with two different random seeds. As can be clearly seen from the blue curves, the condition number is for random DSG configurations in the range of with a plateau value of , while average fractional ani­sotropy is a monotonically decreasing function of . Both and average fractional anisotropy values are more scattered at smaller and less scattered at larger . With isotropic DSG con­figurations (red curves), however, both average fractional anisotropy and condition number at a given are comparatively smaller than with the corresponding random DSG configurations. Moreover, the condition number decreases with an increasing to approximately , where it attains a constant plateau value of , while the average fractional anisotropy monotoni­cally decreases with an increasing . A signifi­cant drop of the average fractional anisotropy from at to at is noticed for both isotropic as well as random DSG configurations. Figure 6 depicts results of numerical simula­tions that were performed with three different pre­set fractional anisotropies (FA = 0.0, 0.1, 0.3) and with two different SNRs (SNR = 5, 30). In the simu­lations random and isotropic DSG configurations with NDSG = 6-100 were considered, while diffusion attenuation was held constant by setting G0 = 0.3 T/m and ./. = 2/15 ms. For each DSG configura­tion, the results are displayed as an average of N. = 100 simulation runs of different noise vectors. As can be seen, the curves of and the curves of are decreasing with an increasing NDSG and SNR; both curve types are decreasing also with an increasing preset FA. Interestingly, the difference of is largest with small NDSG . 10 with both random and isotropic DSG configurations (irre­spective of the preset FA value and SNR). Experimental results of a tap water phantom, examined by 1D DT-MRM are shown in Figure 7 with stack plots of 1D profiles of diffusion tensor quantities ( , , , and ) as a function of . The 1D profiles were measured with isotropic DSG configurations (the same configurations as in Figure 6) along the axis of the cone-shaped phan­tom. As can be seen from the 2D MR image (with­out slice selection) of the phantom and the corre­sponding 1D intensity profile along the phantom 183 axis, SNR decreases monotonically towards the tip of the cone-shaped phantom. From the stack plots it can be seen that diffusion tensor quantities are biased in the phantom regions with poor . The results can be improved by increasing . This can be well seen in the stack plot of , where is the lowest in the encircled region ( ) cor­responding to and the central phantom region with high . Figure 8 shows the experimental DT-MRM re­sults of two bovine cartilage-on-bone samples, i.e., maps of , and as well as the corresponding maps of and , obtained before and after its compression with . The maps were cal­culated from the corresponding magnitude MR im­ages obtained with an isotropic in-plane resolution of either 78 µm (Figure 8A) or 156 µm (Figure 8B). In Figure 8 with the compressed sample, three various regions of interest (ROI1-ROI3) are deline­ated, from which was determined. While ROI1 designates the indenter region (providing no MR signal) for background noise determination, ROI2 and ROI3 designate two regions of weakly and fully compressed cartilage, respectively. The cor­responding values were in the higher-resolu­tion MR images equal to and , while they were equal to and in the lower-resolution MR images. Average values FIGURE 7. Experimental 1D DT-MRM results of the cone-shaped water phantom: 2D MR image of the phantom with the corresponding signal-to-noise ratio (SNR) 1D profile along the phantom axis (top left) and stack plots of the diffusion tensor quantities ( , , , average diffusion coefficient [ADC] and ) as 1D profiles as a function of . Isotropic diffusion sensitizing gradients (DSG) configurations were used. The white dotted curve depicts the region with noticeably reduced fractional anisotropy. TABLE 2. Average values of average diffusion coefficient (ADC) and fractional anisotropy (FA) in three different regions of an uncompressed and compressed cartilage sample obtained with two different spatial resolutions [10-9 m2/s] [1] [10-9 m2/s] [1] Uncompressedcartilage 0.99±0.13 0.27±0.13 1.12±0.14 0.14±0.08 Compression zone 0.63±0.42 0.87±0.27 1.01±0.82 0.82±0.23 Liquid droplet 1.35±0.11 0.24±0.06 1.34±0.19 0.11±0.04 ADC = average diffusion coefficient; FA = fractional anisotropy of and in three different regions (uncom­pressed cartilage, compression zone, liquid ex­pelled from the cartilage tissue) of uncompressed and compressed cartilage obtained with two differ­ent spatial resolutions are given in Table 2. Discussion The aim of this study is to analyze the effect of the signal-to-noise ratio and DSG configuration on noise propagation in the DT-MRM post-process­ing analysis for the isotropic (FA = 0) as well as for anisotropic case (FA > 0). The principal findings of the study are: i) noise propagation in the DT-MRM analysis is manifested in an increased deviation of diffusion tensor eigenvalues; ii) deviations of diffu­sion tensor eigenvalues result to an overestimation of fractional anisotropy, while the average diffusion coefficient remains unchanged; iii) fractional anisot­ropy bias could be reduced by increasing and by optimizing a DSG configuration to a small condi­tion number at a large number of DSG directions. The analysis of numerical simulations is based on correlating the diffusion tensor quantities of isotropic medium with the condition number of the transformation matrix and the number of DSG directions. It was evidently shown (Figures 3-5) that the extent of the fractional anisotropy over­estimation is dependent of the both parameters. Interestingly, noise propagation with random DSG configurations appears in a form of a symmetric deviation of the largest and the smallest diffusion tensor eigenvalue from the expected value of (Figure 3B), while the second diffusion tensor ei­genvalue remains practically unchanged over the entire range of condition numbers. The deviation contributes to an apparent fractional anisotropy considerably, while the deviation is canceled in the calculation of the average diffusion coefficient. With random DSG configurations, an average fractional anisotropy highly correlates with a condition number, which is consistent with et al.12 The minimal values of were obtained with the smallest values of the condition number ( in Figure 3F) corresponding to nearly isotropic DSG configurations, which is in agreement with the results of the study by Batchelor et al.23 This is evident from comparison of minimal as a function of with random DSG configurations (Figure 4A) and of as a function of with isotropic DSG configurations (Figure 5). However, high values of correspond to DSG configura­tions with one or more preferential directions around which DSG directions are clustered. From the results of simulations, it is also evident that the apparent fractional anisotropy decreases with a large number of DSG directions. Namely, the difference between the maximal and the minimal fractional anisotropy in Figure 4A monotonically decreases with an increasing number of DSG direc­tions. The decrease is also associated with a reduc­tion of the corresponding best fit parameters and the fit quality (Figure 4B). Fractional anisotropy overestimation in iso­tropic water phantom was studied by DT-MRM only in 1D due to a required large set of isotropic DSG configurations with different .The experi­ments were performed in 1D to reduce the total acquisition time and for the phantom cone-shaped water-filled sample was used to obtain continuous­ly decreasing along the phantom axis. In 2D DT-MRM of articular cartilage, was reduced additionally due to a faster transversal relaxation and a reduced voxel size, which resulted into an overestimation of fractional anisotropy. The meas­ured values listed in Table 2 are somewhat larger than those in literature.17 The reported fractional anisotropy values in the uncompressed cartilage are equal to in the tangential zone close to the articular surface, in the intermediate zone with disordered collagen fibers and in the radial zone close to the cartilage-bone inter­face, while after compression fractional anisotropy in the compression zone increases to and remained unaltered in other zones. A discrepancy between the measured and the reported values can be attributed mostly to the unfavorable condi­tions. was the lowest in the compression zone, on account of water redistribution from the zone to the articular surface.24 However, the measured fractional anisotropy values in the subchondral bone region were close to unity, which is in an agreement with another high-field DT-MRM study of articular cartilage.25 In comparison to conventional MRI, in MRM, noise has additional origins. Firstly, is usually low due to a much smaller voxel size. Secondly, in MRM imaging gradients are due to an increased spatial resolution large, which in turn contrib­ute to their interaction with DSG. Interaction be­tween DSG and possible background gradients is possible as well. If the contributions are neither compensated by flipping the signs of DSG on al­ternate averages9 nor properly considered in the calculation of transformation matrix elements ac­cording to Eq. 4, variations of the diffusion attenu­ated MR signal within an individual voxel could be misinterpreted as a noise which could lead to an overestimated fractional anisotropy. can be improved by optimizing magnetization recov­ery during each repetition time. The echo time, however, should be set as a compromise between two competing effects, diffusion weighting that in­creases with the echo time and transversal relaxa­tion that decreases with it. A limitation of the study is that the simulations of anisotropic diffusion were performed only with two different SNR values. However, the selected SNRs were taken from DT-MRM experiment on articular cartilage presented in this study. Another limitation of the study is that the experiments on the water phantom were performed only in one di­mension to save experimental time and to thus en­able testing of more DSG configurations. The one dimensional DT-MRM approach would be difficult to apply with cartilage samples due to the tissue heterogeneity, which was even more pronounced after the cartilage compression. Conclusions In this study a possible overestimation of frac­tional anisotropy in DT-MRM was analyzed. It was shown by means of numerical simulations and DT­MRM experiments on the isotropic water phan­tom and low-anisotropy bovine cartilage-on-bone samples that noise propagation from raw data to diffusion tensor eigenvalues can be efficiently re­duced by applying DSG configurations with small condition numbers and large numbers of DSG di­rections. 187 References 1. Assaf Y, Pasternak O. Diffusion tensor imaging (DTI)-based white matter mapping in brain research: A review. J Mol Neurosci 2008; 34: 51-61. 2. Axel L, Wedeen VJ, Ennis DB. Probing dynamic myocardial microstructure with cardiac magnetic resonance diffusion tensor imaging. J Cardiovas Magn Res 2014; 16: 89. 3. Kubicki M, Westin CF, McCarley RW, Shenton ME. The application of DTI to investigate white matter abnormalities in schizophrenia. Ann Ny Acad Sci 2005; 1064: 134-48. 4. Roosendaal SD, Geurts JJ, Vrenken H, Hulst HE, Cover KS, Castelijns JA, et al. Regional DTI differences in multiple sclerosis patients. 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Translational dynamics and magnetic resonance. New York: Oxford University Press; 2011. 11. Bastin ME, Armitage PA, Marshall I. A theoretical study of the effect of experimental noise on the measurement of anisotropy in diffusion imaging. Magn Reson Imaging 1998; 16: 773-85. 12. Skare S, Hedehus M, Moseley ME, Li TQ. Condition number as a measure of noise performance of diffusion tensor data acquisition schemes with MRI. J Magn Reson 2000; 147: 340-52. 13. Pierpaoli C, Basser PJ. Toward a quantitative assessment of diffusion anisot­ropy. Magn Reson Med 1996; 36: 893-906. 14. Jones DK, Knosche TR, Turner R. White matter integrity, fiber count, and other fallacies: the do’s and don’ts of diffusion MRI. NeuroImage 2013; 73: 239-54. 15. Farrher E, Kaffanke J, Celik AA, Stöcker T, Grinberg F, Shah NJ. Novel mul­tisection design of anisotropic diffusion phantoms. Magn Reson Imaging 2012; 30: 518-26. 16. Hellerbach A, Schuster V, Jansen A, Sommer J. MRI phantoms - are there alternatives to agar? PloS one 2013; 8: e70343. 17. de Visser SK, Crawford RW, Pope JM. Structural adaptations in compressed articular cartilage measured by diffusion tensor imaging. Osteoarthritis Cartilage 2008; 16: 83-9. 18. Deng X, Farley M, Nieminen MT, Gray M, Burstein D. Diffusion tensor imaging of native and degenerated human articular cartilage. Magn Reson Imaging 2007; 25: 168-71. 19. Kuchel PW, Pages G, Nagashima K, Velan S, Vijayaragavan V, Nagarajan V, et al. Stejskal-tanner equation derived in full. Concept Magn Reson A 2012; 40A: 205-14. 20. Altschuler EL, Williams TJ, Ratner ER, Tipton R, Stong R, Dowla F, et al. Possible global minimum lattice configurations for Thomson’s problem of charges on a sphere. Phys Rev Lett 1997; 78(14): 2681-2685. 21. Press WH. Numerical recipes in C : the art of scientific computing. 2nd ed. Cambridge Cambridgeshire ; New York: Cambridge University Press; 1992. 22. Rössler E, Mattea C, Stapf S. NMR dispersion investigations of enzymatically degraded bovine articular cartilage. Magn Reson Med 2015; 73: 2005-14. 23. Batchelor PG, Atkinson D, Hill DLG, Calamante F, Connelly A. Anisotropic noise propagation in diffusion tensor MRI sampling schemes. Magn Reson Med 2003; 49: 1143-51. 24. Greene GW, Zappone B, Banquy X, Lee DW, Söderman O, Topgaard D, et al. Hyaluronic acid-collagen network interactions during the dynamic compres­sion and recovery of cartilage. Soft Matter 2012; 8: 9906-14. 25. Raya JG, Melkus G, Dietrich O, et al. Multiparametric characterization of healthy and diseased articular cartilage at 17.6T: Early results. Proc Intl Soc Mag Reson Med 2008; 16: 330. research article The prognostic value of whole blood SOX2, NANOG and OCT4 mRNA expression in advanced small-cell lung cancer Eva Sodja1, Matija Rijavec1, Ana Koren1, Aleksander Sadikov2, Peter Korošec1, Tanja Cufer1 1 University Clinic Golnik, Golnik, Slovenia 2 University of Ljubljana, Faculty of Computer and Information Science, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 188-196. Received 25 February 2015 Accepted 11 June 2015 Correspondence to: Eva Sodja, University Clinic Golnik, Golnik 36, 4204 Golnik, Slovenia. Phone: +386 4 25 69 433; Fax: +386 4 25 69 162; E-mail:eva.sodja@klinika-golnik.si Disclosure: No potential conflicts of interest were disclosed. Background. The data on expression and clinical impact of cancer stem cell markers SOX2, NANOG and OCT4 in lung cancer is still lacking. The aim of our study was to compare SOX2, NANOG and OCT4 mRNA expression levels in whole blood between advanced small-cell lung cancer (SCLC) patients and healthy controls, and to correlate mRNA expression with progression-free survival (PFS) after first-line chemotherapy and overall survival (OS) in advanced SCLC patients. Patients and methods. 50 advanced SCLC patients treated with standard chemotherapy and followed at University Clinic Golnik, Slovenia, between 2009 and 2013 were prospectively included. SOX2, NANOG and OCT4 mRNA expression levels were determined using TaqMan qPCR in whole blood collected prior to chemotherapy. Whole blood of 34 matched healthy individuals with no cancerous disease was also tested. Results. SOX2 mRNA expression was significantly higher in whole blood of SCLC patients compared to healthy con­trols (p = 0.006). Significant correlation between SOX2 mRNA expression levels and the number of distant metastatic sites was established (p = 0.027). In survival analysis, patients with high SOX2 expression had shorter OS (p = 0.017) and PFS (p = 0.046). In multivariate Cox analysis, an independent value of high SOX2 expression for shorter OS (p = 0.002), but not PFS was confirmed. No significant differences were observed for NANOG or OCT4 expression levels when comparing SCLC patients and healthy controls neither when analysing survival outcomes in SCLC patients. Conclusions. SOX2 mRNA expression in whole blood might be a promising non-invasive marker for molecular screen­ing of SCLC and important prognostic marker in advanced chemotherapy-treated SCLC patients, altogether indicat­ing important role of cancer stem-like cell (CSC) regulators in cancer spread. Further evaluation of SOX2 as a possible screening/prognostic marker and a therapeutic target of SCLC is warranted. Key words: small-cell lung cancer; cancer stem cell markers; SOX2; OCT4; NANOG; mRNA expression; prognosis Introduction Lung cancer is the leading cause of cancer-related deaths worldwide, with small-cell lung cancer (SCLC) representing approximately 15% of all lung cancer cases.1,2 SCLC represents one of the most ag­gressive human cancers, with early metastatic dis­semination, initiated by cancer cell intravasation into blood, migration and consequent colonisation of sites distant to primary tumour. Despite some advances in therapeutic approaches, most of the advanced SCLC patients still die within the first year after diagnosis.3,4 SCLC is initially chemosensitive disease, with high response rates achieved with first-line chem­otherapy regimens. However, majority of SCLC patients relapse within a few months and achieve only modest response rates to second-line chemo­ 189 therapy, leading to poor survival rates. Platinum-based chemotherapeutic regimens with cisplatin or carboplatin still represent the only effective sys­temic therapy for SCLC patients. Unfortunately, still, no effective targeted therapy is available in clinical practice to treat SCLC. Classical clinico-pathological characteristics (e.g. age, gender, performance status, stage, burden of metastatic disease) are still the only ones to predict survival outcome of SCLC patients.5.7 Despite an increased effort in identifying additional prognos­tic and predictive molecular markers, none of the so far studied molecular markers proved to have prognostic or predictive value in advanced SCLC.6,7 In the last several years, growing body of evi­dence indicates that cancer stem-like cells (CSCs) behave as crucial actors in cancer development, progression and metastasis.8,9 CSCs have been identified in many human cancer types, including breast cancer10, prostate cancer11, pancreatic can­cer12 and lung cancer.13 For detection and identi­fication of lung CSCs several key regulators have been proposed, normally essential for maintenance of pluripotent state of embryonic stem cells and self-renewal of tissue-specific adult stem cells; these regulators include SRY (sex determining re­gion Y)-box 2 (SOX2)14, homeobox protein NANOG (named after Celtic word Tír na nÓg meaning the land of the young)15 and octamer-binding tran­scription factor 4 (OCT4).16 Cancer stem cells seem to be enriched in tumours resistant to conventional systemic therapy and radiotherapy.17-19 Recent re­ports also suggest that SOX2, NANOG and OCT4 are potential diagnostic and prognostic markers in lung cancer.20-27 Moreover, as indicated by a recent publications28,29, SOX2 is a commonly activated tu­mour oncogene that activates ACT28 and EGFR29 signalling pathways in human cancers, altogether indicating its complex biological role in cell faith. Recent studies mainly conduced in early stage non-small cell lung cancer (NSCLC) after radical surgical therapy correlated SOX2 genomic am­plification and/or consequent protein overexpres­sion in primary tumour tissue with better prog­nosis21,27,30-33; these results were also supported by a meta-analysis, which confirmed significant interaction between high SOX2 expression and improved survival in early NSCLC, regardless of histopathological subtype.22 On the contrary in study evaluating the prognostic value of SOX2 protein expression in primary tumour tissue of early stage SCLC, high SOX2 protein expression was independent prognostic marker for poor sur­vival outcome in SCLC patients.23 So far, only one study quantified the levels of serum SOX2 DNA in patients with different histopathological types and stages of lung cancer.20 In this particular study, se­rum SOX2 DNA level in lung cancer patients was higher compared to the level in healthy group, and it was closely associated with TNM stage, histo­pathological type, and tumour size; unfortunately, the association with course of disease and disease prognosis was not assessed in the frame of the later study. The prognostic value of NANOG and OCT4 has only been evaluated in several retrospective studies with small number of NSCLC patients in­cluded.24-26,34-36 Elevated protein expression of both markers, NANOG24,25,34,35 or OCT424,26,36 in primary tumour was correlated with poor survival out­comes in early NSCLC patients treated with radical surgery. According to our knowledge there are no published data on prognostic or predictive value of NANOG or OCT4 expression in either blood or tumour tissue in SCLC patients. Up to date, various studies have demonstrat­ed that circulating cell-free tumour nucleic acids may reflect the same genetic characteristics as the primary tumour and are therefore attractive for non-invasive biomarkers determination especially during the course of diseases and in patients with no tumour tissue available.37 In lung cancer, pre­viously mentioned study proposed circulating SOX2 DNA levels quantified by fluorescent qPCR as a novel, screening biomarker for lung cancer.20 So far, the prognostic value of SOX2, NANOG or OCT4 mRNA expression in whole blood samples of SCLC patients has not been evaluated yet. Several genetic (e.g. mutations, genomic amplifications) and epigenetic mechanisms, can either decrease or increase the transcription of a particular mRNA38,39; measuring the mRNA expression is therefore an at­tractive approach in cases where there is no known genetic mechanism affecting gene expression. The aim of our study was to evaluate the level of SOX2, NANOG and OCT4 mRNA expression in whole blood samples of advanced SCLC patients compared to healthy controls, and to correlate biomarkers expression with overall survival (OS) and progression-free survival (PFS) after first line chemotherapy in advanced SCLC patients. Patients and methods The present study was conducted and is reported following recommendations for tumour marker prognostic studies (REMARK).40 Patients, healthy volunteers and collection of whole blood samples 50 consecutive patients with pathologically con­firmed advanced SCLC, treated with first-line plat­inum or anthracycline-based chemotherapy and followed at University Clinic Golnik, Slovenia, be­tween December 2009 and June 2013 were prospec­tively enrolled. For comparison, 50 volunteers with no clinical evidence of cancer disease were also in­cluded. Matching criteria were age and gender. 16 volunteers with other chronic pulmonary diseases (chronic obstructive pulmonary disease, asthma) were excluded from this study. For SOX2, NANOG and OCT4 mRNA expres­sion, whole blood samples (2.5 ml; PAXgene Blood RNA Tubes, which contain proprietary solution that reduces RNA degradation and gene induc­tion; Qiagen) were collected from advanced SCLC patients before the onset of chemotherapy and from healthy controls at health check examinees by peripheral venous puncture. All blood samples were obtained after the first 5 ml of blood were dis­carded to avoid contamination of the blood sample with skin epithelial cells and stored at -30°C until RNA isolation. Patients included in this study were treated and followed according to the standard clinical practic­es in use at the time. All patients received first-line systemic therapy with cisplatin-etoposide or carbo­platine-etoposide (PE) or cyclophosphamide–epiru­bicin–vincristine (CEV) chemotherapy. The dosing schedules, dose modifications and supportive ther­apy were offered according to the standard practice. The second-line chemotherapy including CEV or PE was offered at clinician’s discretion. Response to chemotherapy was evaluated according to the RECIST1.1 criteria41 at regular time intervals (every 2-3 months) using chest radiography or comput­erised tomography (CT) scans. Number of distant metastatic sites was defined as the number of the or­gans or organic systems involved in cancer disease. mRNA expression analysis Total RNA was isolated from whole blood using PAXgene Blood miRNA Kit (Qiagen) using the ful­ly automated QIAcube system (Qiagen) to stand­ardize the RNA isolation procedure. Total RNA quantity and purity were assessed using NanoDrop 2000 (ThermoScientific). After isolation and purifi­cation of total RNA from blood samples additional step including digestion of genomic DNA with DNaseI (ThermoScientific) was included. Reverse transcription reactions were performed using the High Capacity cDNA Reverse Transcription Kit (Applied Biosystems). All reagents for RT-PCR were supplied by Applied Biosystems (USA). The expression of stem cell markers was detected by TaqMan RT-qPCR (ABI PRISM 7500 FAST Real-Time PCR System) using gene-specific primers–probe sets (SOX2: Hs01053049_s1, OCT4: Hs00999632_g1, NANOG: Hs02387400_g1) and TaqMan Universal PCR Master Mix II. All measurements were performed in triplicate and relative mRNA expression was determined by the ..Ct method. GAPDH was used as endogenous control and pooled RNA from blood samples of healthy controls was used as a calibrator. All samples with threshold cycle . 38.0 were considered as negative for SOX2, NANOG or OCT4 mRNA expression. Statistics Median relative expression values of each ana­lysed stem cell marker were compared between advanced SCLC patients and healthy controls us­ing the Mann-Whitney U-test. The relationship be­tween SOX2, NANOG or OCT4 mRNA expression and patient characteristics was evaluated using the Mann-Whitney U-test or Fisher’s exact test, as ap­propriate. Overall survival was defined as the period of time in months from the date of diagnosis to the date of death or last follow-up; the secondary end­point PFS was defined as the period of time in months from the start of the first-line chemother­apy to the date of progression or death whichever occurred first. Survival probabilities, OS and PFS, were calculated by the Kaplan-Meier method and log-rank test was used to compare different catego­ries, where optimal cut-off value between low and high expression level was set at the median mRNA expression level for each of the three markers ana­lysed in SCLC patients. The independent prognos­tic value of each individual marker was tested in Cox regression model adjusted for gender, age, PS and the number of distant metastatic sites. A p-val­ue below 0.05 was considered statistically signifi­cant. All statistical analyses were carried out using SPSS (version 21, SPSS, Inc., Chicago, IL, USA). All reported p-values are two-tailed. The study was approved by the Slovenian National Medical Ethics Committee (approval number 135/07/09) before the enrolment of the SCLC patients and healthy controls. The informed consent was ob­tained before the start of the study from all subjects. 191 Results Patient and treatment characteristics Demographic and treatment characteristics of 50 advanced SCLC patients and 34 healthy volun­teers are listed in Table 1. At the time of diagnosis, median age of patients was 65 years (range 46-88 years), majority of the patients were male (35/50; 69%), and in good PS (PS . 1 in 38/50; 76%). As first-line chemotherapy, the majority of patients re­ceived platinum-based chemotherapy (42/50; 84%). The second line chemotherapy was offered to 14/50 (28%) patients. Evaluation of SOX2, OCT4 and NANOG mRNA expression SOX2 relative mRNA expression levels were de­tected in 46/50 (92%) blood samples of advanced SCLC patients and in 25/34 (73%) blood samples of healthy controls. SOX2 mRNA expression levels were significantly higher in whole blood samples of SCLC patients when compared to healthy con­trols (median: 0.8 (range: 0.0-11.1) vs. 0.6 (range: 0.0-1.8), respectively, p = 0.006; Figure 1). On the other hand, NANOG and OCT4 relative mRNA expression levels were detected in all blood sam­ples of SCLC patients and healthy controls. In ad­dition, no significant differences were observed in NANOG (median: 1.5 (range: 0.4-4.8) vs. 1.2 (range: 0.4-4.4), respectively; p = 0.199, Figure 1) and OCT4 (median: 1.5 (range: 0.4-3.3) vs. 1.2 (range: 0.3-3.4), respectively; p = 0.224; Figure 1) median mRNA levels between SCLC patients and healthy group. As already mentioned in the methods section, cut-off value between low and high mRNA expres­sion was set at the median expression level for the three markers analysed in SCLC patients. The as­sociations between SOX2, NANOG or OCT4 mR-NA expression and clinical variables are shown in Table 2. High SOX2 mRNA expression was corre­lated with the higher number of distant metastatic sites (p = 0.027). There were no other significant correlations between SOX2, NANOG or OCT4 mR-NA expression and other clinical variables, such as gender and age. Survival analysis After the median follow-up of 8.5 months (range: 0.5-32.5 months) median PFS was 6.2 months and median OS was 8.4 months in 50 SCLC patients in­cluded into analysis. TAblE 1. Characteristics of small-cell lung cancer (SCLC) patients and healthy volunteers Age in years: median (range) 65 (46-88) 62 (47-78) Gender, N (%) Male 34 (68) 24 (71) Female 16 (32) 10 (29) PSa, N (%) 0–1 38 (76) . 2 12 (24) Number of distant metastatic sites, N (%) < 3 34 (68) . 3 16 (32) Type of first-line chemotherapy, N (%) PE 42 (84) CEV 8 (16) aEast Cooperative Oncology Group performance status; CEV = cyclophosphamide-epirubicin­vincristine; N = number of SCLC patients/healthy volunteers; PE = platinum (cisplatin or carboplatin)-etoposide The level of SOX2 mRNA expression, signifi­cantly influenced both PFS after first-line chemo­therapy (p = 0.046; Table 3, Figure 2A) and OS (p = 0.017; Table 3, Figure 3A) in our patients, with high SOX2 being associated with poor PFS and OS. Furthermore, in multivariate analysis inde­pendent prognostic value of SOX2 expression was confirmed for OS (p = 0.002; Table 3). On the other hand, no significant correlation between NANOG TAblE 2. Association between SOX2, NANOG and OCT4 mRNA expression and patients` characteristics Age in years: median (range) 63 (46–78) 66 (47–88) 0.301c 65 (47–79) 65 (46–88) 0.648 c 64 (47–77) 66 (46–88) 0.466 c Gender, N (%) 0.756d 0.762d Male 12 (35) 22 (65) 18 (53) 16 (47) 16 (47) 18 (53) 0.762d Female 7 (44) 9 (56) 7 (44) 9 (56) 9 (56) 7 (44) PSa, N (%) 0.332d 0.742d 1.000d 0–1 16 (42) 22 (58) 20 (53) 18 (47) 19 (50) 19 (50) . 2 3 (25) 9 (75) 5 (42) 7 (58) 6 (50) 6 (50) Number of distant metastatic sites, 0.027d 0.762d 1.000d N (%) < 3 9 (26) 25 (74) 18 (53) 16 (47) 17 (50) 17 (50) . 3 10 (62) 6 (38) 7 (44) 9 (56) 8 (50) 8 (50) N = number of patients; a East Cooperative Oncology Group performance status; bmedian mRNA expression levels for each of the three markers analysed were used to stratify patients as either SOX2/NANOG/OCT4 low or high; cMann-Whitney U-test; dFisher’s exact test or OCT4 expression and survival outcomes was ob­served in univariate (Table 3, Figures 2-3) or multi­variate analysis (Table 3). Discussion The present study aimed to compare SOX2, NANOG and OCT4 mRNA expression in whole blood between advanced SCLC patients and healthy controls, and to assess the prognostic im­pact of mRNA expression in 50 advanced SCLC pa­tients treated with first-line chemotherapy, either platinum or anthracycline-based. Only SOX2 mR-NA levels were significantly higher in advanced SCLC patients when compared to healthy controls. Moreover, elevated SOX2 expression levels had an independent prognostic value for better OS in ad­vanced chemotherapy-treated SCLC. Our results indicate significantly higher SOX2 mRNA expression in whole blood of SCLC pa­tients when compared to healthy controls, and are consistent with the only study which observed significantly higher serum SOX2 DNA levels in 94 patients with different histopathological types and stages of lung cancer in comparison to benign lung disease group or healthy group.20 Moreover, we observed a significant positive correlation between high SOX2 mRNA expression in whole blood and the higher number of distant metastatic sites (p = 0.027), suggesting that SOX2 expression might mirror an important oncogenic and metastatic po- TAblE 3. Progression-free survival (PFS) after first-line chemotherapy and overall survival (OS) according to SOX2, NANOG and OCT4 mRNA expression All patients (N = 50) 6.2 8.4 SOX2 low 7.4 9.9 0.046 0.377 0.017 0.002 1.988 (1.011-3.922) 1.054 (0.938-1.183) 2.370 (1.164-4.831) 3.205 (1.536-6.711) SOX2 high 5.6 7.5 NANOG low 5.7 7.4 0.221 0.299 0.347 0.376 0.693 (0.384-1.247) 0.864 (0.656-1.139) 0.750 (0.412-1.366) 0.884 (0.674-1.161) NANOG high 6.5 8.7 OCT4 low 5.6 7.8 0.156 0.227 0.251 0.416 0.652 (0.362-1.178) 0.780 (0.521-1.167) 0.810 (0.446-1.471) 0.891 (0.673-1.178) OCT4 high 7.3 9.9 95% CI = 95% confidence interval; HR = hazard ratio; MV = multivariate analysis adjusted for age, gender, N = number of patients; PS and the number of distant metastatic sites; relative expression values for each of the three markes analysed were used in MV; UV = univariate analysis; Log-rank test was used to analyse different categories dichotomised according to the median mRNA expression levels for each of the three markers analysed 193 tential in SCLC. Furthermore, correlation between high SOX2 mRNA expression and both poorer PFS after first-line chemotherapy (p = 0.046) and poorer OS (p = 0.017) was observed; association between high SOX2 expression and poor OS (p = 0.002) per­sisted also in multivariate analysis. Our findings obtained in whole blood of SCLC patients, seem to be consistent with the only study evaluating the prognostic value of SOX2 protein expression in SCLC primary tumours obtained after surgery, where high SOX2 protein expression in the prima­ry tumour proved to be an independent prognostic marker for worse OS and shorter recurrence-free survival in patients with early stage SCLC who un­derwent surgery.23 In contrast to SCLC, high SOX2 protein expres­sion and SOX2 gene amplification in primary tu­mours seem to be associated with better prognosis in NSCLC.22 These contradictory results might be due to different methodologies of biomarker deter­mination (e.g. fluorescent in situ hybridization or quantitative PCR for detection of SOX2 genomic amplification, immunohistochemistry for SOX2 protein expression), small number of patients in­cluded in our study or may even suggest cancer-specific role of SOX2 in different histopathological types of lung cancer. Detection of mRNA expression levels of selected biomarkers in whole blood is relatively new con­cept in lung cancer or any other human cancer that could be developed as an ancillary tool for disease screening and monitoring. Furthermore, it might represent an attractive approach for evaluating gene expression with no known underlying genet­ic mechanism affecting its expression. Moreover, detection of tumour specific DNA alterations42 and differential mRNA expression43-46 in primary tumours and/or circulating nucleic acids by high-throughput technologies (next-generation se­quencing, microarrays) may provide a substantial advance in monitoring disease burden and treat­ment response in all human cancers. The cut-off point for SOX2 positivity was set at the median value of SOX2 mRNA expression. Of note, there are no clinically validated cut-off values for SOX2 mRNA expression available in lung can­cer, because this is the first study evaluating SOX2 mRNA expression in lung cancer. Studies conduct­ed in other human cancers, including prostate can­cer, rectal cancer, and hepatocellular cancer, so far used different, not yet validated thresholds based on the cohort of the included patients.47-49 Our results indicate no difference in NANOG and OCT4 mRNA expression levels in whole blood when comparing SCLC patients and control group. Moreover, no correlation between NANOG and OCT4 expression in whole blood and survival outcomes was observed in our study. To our best knowledge, the diagnostic and prognostic value of NANOG and OCT4 mRNA expression in tumour tissue or whole blood has not yet been evaluated in SCLC. However, several retrospective studies with small number of NSCLC patients included associated high NANOG or high OCT4 protein expression in primary tumour with poor survival outcome of NSCLC patients treated mainly with curative surgical resection.24-26,34-36 Again, these dif­ferences might be due to different methodologies of biomarker determination, low number of pa­tients or specific role of these two markers in histo­pathological types of lung cancer. The present study has several potential limita­tions, such as the small sample size that has an im­pact on statistical power of survival analysis and could therefore greatly limit the accuracy of the results. Furthermore, there are still methodologi­cal issues of biomarkers determination that should be appropriately resolved. The methods currently used for the evaluation of SOX2, NANOG or OCT4 expression in lung cancer patients differ greatly among the published reports. Studies conducted in lung cancer mainly used immunohistochemis­try (IHC) for SOX2, NANOG and OCT4 protein expression and fluorescence in situ hybridisation (FISH) or quantitative PCR (qPCR) for SOX2 gene amplification detection.21-26,31-33 Besides, there are no clinically validated cut-off values for SOX2, NANOG and OCT4 mRNA expression available in the published literature and major differences still exists regarding the cut-off values of defining the specimens as positive/high for SOX2, NANOG or OCT4 expression determined either by IHC, FISH qPCR.21-26,31-33 or Furthermore, transcription of NANOG and OCT4 pseudogenes was reported in some tumour tissues and their detection by qPCR could give false-positive results.50,51 Unfortunately, direct comparison of SOX2, NANOG and OCT4 mRNA expression between whole blood and pri­mary tumour tissue was not assessed in the frame of our study due to low number of patients with available tumour tissue. Further studies evaluating the correlation between gene expression profiles in whole blood and primary tumour tissue would be of valuable to assess the potential similarity of gene expression characteristics between blood circula­tion and primary lung tumour. In conclusion, our prospective observational study found significantly higher mRNA expres­sion levels of SOX2 in whole blood samples of ad­vanced SCLC patients when compared to healthy controls. Equally importantly, a possible prognos­tic value of SOX2 mRNA expression for overall survival of SCLC patients was observed. No such correlations were found for NANOG or OCT4 ex­pression. Our findings support the emerging on­cogenic and metastatic role of SOX2 in SCLC with potential applications as a prognostic CSC marker and therapeutic target in lung cancer. 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Exp Cell Res 2012; 318: 1799-807. 197 research article Tenckhoff tunneled peritoneal catheter placement in the palliative treatment of malignant ascites: technical results and overall clinical outcome Geert Maleux1, Inge Indesteege1, Annouschka Laenen2, Chris Verslype3, Ignace Vergote4, Hans Prenen3 1 Department of Radiology, University Hospitals Leuven, Belgium 2 Department of Biostatistics and and Statistical Bioinformatics, KU Leuven and Universiteit Hasselt, Belgium 3 Department of Digestive Oncology, University Hospitals Leuven, Belgium 4 Department of Gynaecology, University Hospitals Leuven, Belgium Radiol Oncol 2016; 50(2): 197-203. Received 13 October 2015 Accepted 20 December 2015 Correspondence to: Geert Maleux, M.D., Ph.D., Department of Radiology, University Hospitals Leuven, Herestraat 49, B-3000 Leuven; Belgium. Phone: +32 16 34 37 82; Fax: +32 16 34 37 65; E-mail: geert.maleux@uzleuven.be Disclosure: The authors have no conflicts of interest to disclose. Background. To assess the technical and clinical outcome of percutaneous insertion of tunneled peritoneal cath­eters in the palliative treatment of refractory malignant ascites and to determine the safety and feasibility of intraperi­toneal administration of cytotoxic drugs through the tunneled catheter. Materials and methods. Consecutive patients palliatively treated with a tunneled peritoneal catheter to drain the malignant ascites were identified. Patients’ medical history, procedural and clinical follow-up data, including compli­cations and estimated survival, were reviewed. Additionally, a sub analysis of the patients with widespread ovarian cancer and refractory ascites treated with or without intraperitoneal administration of cytotoxic drugs was made. Results. In all 94 patients it was technically feasible to insert the peritoneal drainage catheter and to drain a median of 3260 cc (range 100 cc – 8500 cc) of malignant ascitic fluid. Post procedural complications included catheter infec­tion (n = 2; 2%), fluid leakage around the entry site (n = 4; 4%), catheter occlusion (n = 2; 2%), sleeve formation around the catheter tip (n = 1; 1%) and accidental loss of the catheter (n = 1; 1%). There was no increase in catheter infection rate in patients treated with or without intraperitoneal administration of cytotoxic drugs. Median overall survival after catheter insertion is 1.7 months. Conclusions. Percutaneous insertion of a tunneled Tenckhoff catheter for the palliative drainage of malignant ascites and intraperitoneal infusion of cytotoxic drugs is feasible and associated with a very low complication rate, including catheter infection. These tunneled peritoneal lines are beneficial for symptomatic palliative treatment of refractory ascites and allow safe intraperitoneal chemotherapy. Key words: peritoneal catheter; malignant ascites; palliation Introduction Malignant ascites is a manifestation of terminal metastatic disease with a life expectancy ranging from 1 to 4 months; the ascitic fluid production is usually associated with peritoneal tumours, lym­phangitic carcinomatosis, lymphatic obstruction, encasement of the portal vein by a tumour caus­ing prehepatic portal hypertension, or a combina­tion of these pathophysiological mechanisms.1-3 Clinically, these patients suffer from abdominal distension, early satiety, shortness of breath, fa­tigue or gastrointestinal symptoms such as nausea and vomiting. Medical treatment, including diuret­ics, have little or no effect on malignant fluid accu­mulation and the standard treatment for these pa­tients was repeated paracentesis, despite the risks of infection, haemorrhage or bowel wall injury and the need for frequent trips to the hospital.4 In the past decade, alternative drainage options intended to avoid repetitive punctures, have been tested and used. These drainage techniques include internal drainage like peritoneo-venous5, peritoneo-gas­tric6 and peritoneo-cystic7 shunting and external drainage techniques requiring the placement of an indwelling, tunneled peritoneal drainage or port­catheter.2,3,5,8-13 An important disadvantage of exter­nal drainage is albumin loss, which may need to be considered in deciding between external drainage and internal shunts. Most of the experience with indwelling drainage catheters has been described with the PleurX catheter; this monocuffed catheter was initially designed for drainage of malignant pleural effusions but it can also be used for drain­age of malignant peritoneal fluid.3,9-11 Additionally, if this type of indwelling tunneled catheter is used, it is recommended to use vacuum bottles for ad­equate drainage. In this study we retrospectively analysed the technical feasibility and safety of the inser­tion of a Tenckhoff peritoneal tunnelled catheter. Additionally, the overall clinical outcomes in this patient population were analysed and finally we evaluated the feasibility and safety of intraperito­neal chemotherapy delivery through the Tenckhoff catheter in patients with widespread ovarian can­cer and refractory ascites using catumaxomab. Materials and Methods Patients and study design A retrospective analysis was carried out on con­secutive patients in whom a Tenckhoff tunnelled peritoneal catheter was inserted percutaneously for the management of refractory malignant ascites in the authors’ institution between March 2006 and January 2013. The inclusion criteria for catheter placement were symptomatic, malignant ascites refractory to conservative and medical manage­ment in patients with widespread metastatic dis­ease; haemostatic parameters allowing small skin incisions and subcutaneous tunnelling; absence of compartmentalization of the malignant ascitic fluid. Active infection is considered as an exclu­sion criterion for catheter insertion. Refractory malignant ascites is defined as ascites in patients with widespread metastatic disease in whom the ascites cannot be mobilized by conservative or medical therapies. Patients’ history, procedural and post-procedural data were documented based on the patients’ hospital electronic medical records and after telephone calls with the patients’ general practitioners. The patients gave informed consent before the start of the interventional procedure and institu­tional review board approval was obtained for this retrospective study analysis. Interventional procedure of Tenckhoff catheter placement Patients were referred to the interventional radiol­ogy department after discussion between the at­tending interventional radiologist and medical or surgical oncologist. Patient preparation included a bedside ultrasound for evaluation of the amount of ascites and more specifically for evaluation of a window of ascitic fluid at the intraperitoneal punc­ture site. The preferred intraperitoneal puncture site was near the midline, inferior and to the right of the umbilicus; if no ascitic fluid window was identified in that area, a left-sided infra-umbilical puncture site was prepared with a tunnel area to the left flank. Laboratory analysis included ac­ceptable haematological parameters for tunneled catheter insertion, including a platelet count of at least 50,000/L, a haemoglobin level > 8 g/dL and an International Normalized Ratio (INR) of less than 1.5. Tenckhoff tunneled peritoneal drainage cath­eter insertion was performed under sterile condi­tions in the interventional radiology suite. After standard surgical preparation, local anaes­thesia of the puncture site and the subcutaneous tunnel area was administered with 30 mL of lido­caine hydrochloride (Linisol 2%, B. Braun, Diegem, Belgium). No other sedation or prophylactic anti­biotic medication was administered; a 2 cm skin incision was made near the midline, inferior and to the right (or left) of the umbilicus and ultrasound-guided puncture of the malignant ascitic fluid was carried out using an 18 gauge (G) sheathed nee­dle (Surflo I.V. Catheter, Terumo Europe, Leuven, Belgium) (Figure 1A). A 0.035 inch hydrophilic guide wire (HydroSteer, St-Jude Medical, St-Paul, MN, USA) was introduced into the peritoneal cav­ity using a 0.035 inch 4 French (F) Cobra catheter (Slip-cath, Cook Medical, Bjaeverskov, Denmark) positioned in the pelvis (Figure 1B). This was then exchanged for a 0.035 inch stiff guide wire (Amplatz, Cook Medical, Bjaeverskov, Denmark) (Figure 1C). Over the stiff guide wire the punc­ 199 ture tract was dilated using a 8F dilator (Cook Medical, Bjaeverskov, Denmark) and finally a 15F peel-away introducer (PTFE-peel-Apart, BARD Benelux, Olen, Belgium) was inserted (Figure 1D). The Tenckhoff peritoneal drainage catheter (Argyle peritoneal dialysis catheter, Covidien, Mansfield, MA, USA) with the Cobra catheter inside was in­troduced over the stiff guide wire into the perito­neal cavity and positioned in a curved position in the lower pelvic region (Figure 1E). The Tenckhoff catheter is made of translucent silicone rubber tub­ing containing a radio-opaque stripe. The total length of the 15F catheter is 47 cm and the inner diameter is 2.6 mm. The intraperitoneal part of the catheter contains small fenestrations over a length of 15 cm (Figure 2). The cuffed end of the Tenckhoff catheter is tunnelled to the right (or left) flank us­ing a metallic tunnelling device (Argyle Faller Tunneling device, Covidien, Mansfield, MA, USA) and exteriorized 7 cm lateral to the peritoneal en­try site. Finally, the small cutaneous incisions are sutured and the external part of the tunnelled cath­eter is connected to a drainage bag (3L Empty Bag System II, Baxter Healthcare, Zurich, Switzerland) using a sterile connecting device (Connection Shield System II with Povidone-Iodine Solution, Baxter Healthcare, Zurich, Switzerland) to begin drainage. The intraperitoneal chemotherapy infusion technique was performed using a catumaxomab­based regimen as described by Baumann et al.14 Briefly, catumaxomab (Removab®, Neovii Biotech, Waltham, MA, USA) 10 µg, 20 µg, 50 µg and 150 µg in 250 mL of 0.9% NaCl physiologic solution was injected intraperitoneally through the Tenckhoff catheter, respectively at day 1, 4, 8 and 11 of the treatment. Patients were followed up until the end of the study (March 2013) or the patient’s death. FIGURE 2. Schematic drawing of the Tenckhoff catheter: the intraperitoneal portion contains small fenestrations over a length of 15 cm. Two cuffs with a length of 1 cm are positioned in the subcutaneous tissues. Statistical analysis Overall survival probabilities are estimated by the Kaplan-Meier method. The Wilcoxon test is used for testing survival differences between ovarian cancer patients with or without intraperitoneal chemotherapy treatment (IPCT). The prognostic value of primary pathology for survival is analysed using Cox proportional hazards models. Fisher’s exact test is used for the association between intra­peritoneal chemotherapy treatment and catheter infection. All tests are two-sided. A 5% significance level is assumed for all tests. All analyses have been car­ried out using SAS software, version 9.3 of the SAS System for Windows (SAS Institute Inc., Cary, NC, USA). Results Patient demographics In 94 patients (27 men; 28.7% and 67 women; 71.3%) with a mean age of 60.1 years (median 59.4 years; standard deviation 12.4 years) a tunnelled perito­neal Tenckhoff catheter was inserted for drainage of malignant ascites. Malignant ascites was associ­ated with different types of metastatic cancer dis­ease as summarized in Table 1. The category ‘rest’ included lung carcinoma (n = 2), multiple myeloma (n = 2) and myxoid liposarcoma (n = 1). TABLE 1. Type of primary cancer Gynaecological cancer n/N (%) 41/94 (43.6%) Ovarian cancer n/N 38/94 Endometrial cancer n/N 3/94 Hepatobiliary cancer n/N (%) 24/94 (25.5%) Pancreatic cancer n/N 11/94 Cholangiocarcinoma n/N 12/94 Hepatocellular carcinoma n/N 1/94 Gastrointestinal cancer n/N (%) 11/94 (11.7%) Colorectal cancer n/N 6/94 Gastric cancer n/N 3/94 Small bowel neuroendocrine cancer n/N 2/94 Breast cancer n/N (%) 13/94 (13.8%) Rest n/N (%) 5/94 (5.3%) TABLE 2. Paracenteses prior to Tenckhoff catheter placement 0 n/N (%) 19/94 (20.2%) 1 n/N (%) 20/94 (21.3%) 2 n/N (%) 16/94 (17.0%) 3 n/N (%) 15/94 (16.0%) 4 or > 4 n/N (%) 24/94 (25.5%) TABLE 3. Kaplan-Meier estimates for overall survival since Tenckhoff insertion at specific follow-up times (+95% confidence interval) 3 30.0 20.9 39.6 6 18.0 10.8 26.8 12 7.7 3.2 14.5 18 2.6 0.3 9.9 24 2.6 0.3 9.9 The number of paracenteses prior to Tenckhoff catheter insertion is indicated in Table 2; overall, patients underwent a mean of 3.4 paracenteses (median: 2.0; standard deviation: 5.6; range: 0–44 paracenteses). In 15 out of 94 patients (16%) intra­peritoneal chemotherapy treatment (IPCT) with catumaxomab was given; these 15 patients suffered from widespread metastatic ovarian cancer associ­ated with refractory malignant ascites. Technical outcome In all patients (100%), the Tenckhoff tunnelled peri­toneal drainage catheter was successfully inserted; in 90 patients (96%), the Tenckhoff catheter was tunnelled subcutaneously into the right flank, in the remaining 4 patients (4%) the peritoneal access was made in the left para and infraumbilical region and the catheter was tunnelled into the left flank. Once the Tenckhoff catheter was in place, a median of 3,260 cc (range 100 cc – 8,500 cc) of malignant ascitic fluid was drained. Clinical outcome Clinical follow-up was available for 90 patients; 4 patients (4.2%) were lost to follow-up. Two patients (2.1%) presented with a clinical suspicion of catheter infection, including fever, painful cutaneous and subcutaneous tunnel infec­tion, but without clear signs of peritonitis, 36 & 40 days respectively after initial catheter placement. One of these two patients was also treated with intraperitoneal chemotherapy infusions. Other minor complications included ascitic fluid leak­age around the entry point of the catheter in the right flank (n = 4; 4%), catheter occlusion (n = 2; 2%) and sleeve formation around the tip of the cath­eter resulting in insufficient drainage (n = 1; 1%). Management of these complications included extra skin sutures around the catheter entry point (n = 4), catheter removal (n = 1) or catheter flushing (n = 2) respectively. In another three patients (3%), initially present­ing with malignant ascites related to breast carci­noma (n = 1), endometrial carcinoma (n = 1) and ovarian carcinoma (n = 1), the Tenckhoff catheter was removed after 111, 134 and 39 days respective­ly, owing to regression of ascitic fluid production. Another patient accidentally lost the catheter 11 days after initial placement. Five out of 90 patients (5.3%) were still alive at the end of the study (March 2013); the remaining 85 patients (90.4%) died before March 2013. The time interval until end of follow-up or the patient’s death was a mean of 3.41 months (median 1.7 months; standard deviation: 4.73; min: 0.03, max 25.7 months). Kaplan-Meier estimates for overall survival after Tenckhoff insertion is summarized in Figure 3 and Table 3, showing an estimated survival at 3 and 6 months of nearly 30% and 18% respectively. Further, a more detailed analysis of survival after Tenckhoff catheter insertion is made based on the underlying FIGURE 5. Overall estimated survival since clinical diagnosis of malignant ascites with 95% confidence limits. type of cancer. We analysed five categories of un­derlying aetiologies: gynaecological cancers (n = 40) including ovarian and endometrial cancers; hepato­biliary cancers (n = 22) including pancreatic cancer, cholangiocarcinoma and hepatocellular carcinoma; 201 TABLE 4. Kaplan-Meier estimates for overall survival since clinical diagnosis of ascites at specific follow-up times (+ 95% confidence interval) 3 82.2% 72.6% 88.7% 6 63.2% 53.3% 72.2 % 12 44.7 % 34.1% 54.7% 18 30.6% 21.2% 40.4% 24 24.7% 16.2% 34.1% TABLE 5. Analysis of overall survival since clinical diagnosis of malignant ascites for different groups of cancers Gynaecological cancers (reference) - - - 0.06 Hepatobiliary cancers 1.17 0.68 2.02 0.575 Gastrointestinal cancers 2.58 1.30 5.13 0.007 Breast cancer 1.42 0.73 2.74 0.299 Rest 0.71 0.25 1.99 0.511 gastrointestinal cancers (n = 11) including colorectal cancer, gastric cancer and neuroendocrine tumours; breast carcinoma (n = 11) and rest (n = 5) includ­ing lung carcinoma (n = 2), multiple myeloma (n = 2) and myxoid liposarcoma (n = 1); the survival of these different groups is summarized in Figure 4. Analysis suggests a difference in risk for early death after Tenckhoff catheter insertion according to the underlying cancer: patients with widespread gastrointestinal cancers and refractory malignant ascites have a higher risk for early death compared to the reference group of patients with widespread metastatic gynaecological cancers. TABLE 6. Survival analysis in patients with metastatic ovarian cancer and malignant ascites treated with or without intraperitoneal infusion of catumaxomab after Tenckhoff catheter insertion With IPCT 3.22 1.61 6.58 Without IPCT 1.61 0.69 2.40 IPCT = intraperitoneal chemotherapy treatment Overall survival after clinical diagnosis of ma­lignant ascites demonstrates a 3 and 6 month es­timated survival of 82.0% and 63.9% respectively, as shown in Table 4 and Figure 5. An analysis of the potential outcome differences between the five categories of cancer mentioned above was carried out and summarized in Table 5 and Figure 6. The risk analysis for early death after clinical diagnosis of malignant ascites also demonstrates a significant difference in survival for patients with malignant gynaecological cancer compared to patients with gastrointestinal cancers (p = 0.007). Tunnelled Tenckhoff catheters were inserted in a total of 38 patients presenting with metastatic ovarian cancer and malignant ascites. In 23 of these patients the Tenckhoff catheter was inserted solely for repeated drainage purposes. In the remaining 15 patients the Tenckhoff catheter was inserted for the purpose of drainage of malignant ascites and for the purpose of intraperitoneal infusion of a ca­tumaxomab-based solution. Overall survival of the two sub-groups of patients (Table 6 and Figure 7) revealed better survival in the group with intra­peritoneal infusion of catumaxomab (p = 0.02). Discussion This study demonstrates a very high technical suc­cess rate (100%) for tunnelled, peritoneal Tenckhoff catheter insertion in patients suffering from re­fractory malignant ascites, which is in line with experiences in other centres using the same2,15 or other types of tunnelled peritoneal catheters such as the PleurX-catheter3,8-11 or Medcomp catheter.16 Furthermore, subcutaneous insertion of port cath­eters has a 100% success rate12,13, although there are only a few reports covering a small number of in­cluded patients. The major difference between the PleurX catheter and the Tenckhoff or Medcomp catheter is the number of cuffs: the PleurX catheter has one cuff whereas the other two have two cuffs; the number of infection events with these differ­ent types of tunnelled catheters does not, however, seem to be different: we encountered two patients (2%) with clinical signs of infection which is almost identical to the series with the PleurX catheter.9,11 The technique of tunnelled catheter insertion is essentially the same for the different types of peri­toneal tunnelled catheters: percutaneous access to the peritoneal cavity is gained under ultrasound guidance using Seldinger technique and insertion of the catheter through a peel-away sheath can be performed blindly or under fluoroscopic guid­ance. When using these techniques, however, the position of the tip of the tunnelled catheter is not always predictable. Instead, we used a catheter-based technique (Cobra catheter and hydrophilic guide wire) to position the tip and the fenestrated area of the Tenckhoff catheter in the dependent portion of the peritoneal cavity (lower pelvic re­gion) which might result in better drainage of the ascitic fluid later on, especially when the patient is in a sitting or supine position, although catheter tip migration after insertion is still possible especially in case of recurrent ascitic fluid accumulation asso­ciated with bowel and body movements in general. Other post-procedural complications apart from infection are almost always minor complications and may include fluid leakage around the catheter entry point, catheter occlusion or accidental loss despite the presence of two cuffs. This very low rate of serious complications may suggest earlier referral for Tenckhoff catheter placement for the palliative drainage of malignant ascites resulting in patients’ improved quality of life. Importantly, this study also suggests the useful­ness of the Tenckhoff catheter for intraperitoneal administration of chemotherapeutic agents such as catumaxomab without a significant increase in 203 adverse, infectious events, although the number of patients treated with intraperitoneal chemothera­py infusion was small (n = 15). The life expectancy of patients with refractory malignant ascites is very poor, with a range from 1 to 4 months, which is in line with the overall results of this study, showing a median overall survival of 1.7 months. This short life expectancy mainly depends on the natural history of the underlying widespread malignancy and subsequently patients with a longer life expectancy associated with re­fractory malignant ascites, such as patients with gynaecological tumours, may also benefit from the tunnelled Tenckhoff catheter for a longer pe­riod compared to patients with more aggressive tumours such as gastrointestinal malignancies. Finally, a sub-analysis of patients with refrac­tory ascites and widespread malignant ovarian tu­mours reveals improved survival if catumaxomab is administered intraperitoneally (p = 0.02). This conclusion should be interpreted with caution, however, because this is a retrospective, single-centre, non-randomized analysis including a small number of patients. Additionally, a multi-centre, randomized open-label phase IIa study was only able to demonstrate a slightly better therapeutic in­dex in a high-dose catumaxomab regimen as com­pared to a low-dose regimen14 and other research­ers found a non-significant survival benefit (110 days versus 81 days) if intraperitoneal administra­tion of catumaxomab took place in patients with recurrent ovarian cancer.17 In conclusion, this study demonstrates that per-cutaneous image-guided insertion of a tunnelled Tenckhoff catheter in the peritoneal cavity is safe and effective for drainage of refractory malignant ascites, with a very low complication rate including catheter infection. The catheter is also an efficient and safe tool for intraperitoneal administration of cytotoxic drugs with no increase in peritonitis or other infectious adverse events. Finally, owing to the natural course of the underlying malignant tu­mor, patients with widespread metastatic gynaeco­logical cancers and refractory ascites may benefit for a longer period from this interventional proce­dure than patients with other cancers and associ­ated malignant ascites. References 1. Mullard A, Bishop J, Jibani M. Intractable malignant ascites: An alternative management option. J Palliative Med 2011; 2: 251-3. 2. O’Neill M, Weissleder R, Gervais D, Hahn P, Mueller P. Tunneled peritoneal catheter placement under sonographic and fluoroscopic guidance in the palliative treatment of malignant ascites. Am J Roentgenol 2001; 177: 615-8. 3. Richard H, Coldwell D, Boyd-Kranis R, Murthy R, Van Echo D. Pleurx tunneled catheter in the management of malignant ascites. J Vasc Intervent Radiol 2001: 12: 373-5. 4. Belfort M, Stevens P, DeHaek K, Soeters R, Krige J. A new approach to the management of malignant ascites; a permanently implanted abdominal drain. Eur J Surg Oncol 1990; 16: 47-53. 5. Arai Y, Inaba Y, Sone M, Saitoh H, Takeuchi Y, Shioyama Y, et al. Plase I/ II study of transjugular transhepatic peritoneovenous venous shunt, a new procedure to manage refractory ascites in cancer patients: Japan Interventional Radiology in Oncology Study Group 0201. Am J Roentgenol 2011; 196: W621-W626. 6. Lorentzen T, Sengelov L, Nolsoe CP, Khattar SC, Karstrup S, von der Maase H. Ultrasonically guided insertion of a peritoneo-gastric shunt in patients with malignant ascites. Acta Radiol 1995; 36:481-4. 7. Stehman F, Ehrlich C. Peritoneo-cystic shunt for malignant ascites. Gynecol Oncol 1984; 18: 402-7. 8. Rosenberg S, Courtney A, Nemcek A, Omary R. Comparison of percuta­neous management techniques for recurrent malignant ascites. J Vasc Intervent Radiol 2004; 15: 1129-31. 9. Tapping C, Ling L, Razack A. PleurX drain use in the management of malig­nant ascites: safety, complications, long-term patency and factors predictive of success. Br J Radiol 2012; 85: 623-8. 10. Lungren M, Kim C, Stewart J, Smith T, Miller M. Tunneled peritoneal drain­age catheter placement for refractory ascites: Single-center experience in 188 patients. J Vasc Intervent Radiol 2014; 24: 1303-8. 11. Courtney A, Nemcek A, Rosenberg S, Tutton S, Darcy M, Gordon G. Prospective evaluation of the PleurX catheter when used to treat malig­nant ascites associated with malignancy. J Vasc Intervent Radiol 2008; 19: 1723-31. 12. Savin M, Kirsch M, Romano W, Wang S, Arpasi P, Mazon C. Peritoneal ports for treatment of intractable ascites. J Vasc Intervent Radiol 2005; 16: 363-8. 13. Ozkan O, Akinci D, Gocmen R, Cil B, Ozmen M, Akhan O. Percutaneous placement of peritoneal port-catheter in patients with malignant ascites. Cardiovasc Intervent Radiol 2007; 30: 232-6. 14. Baumann K, Pfisterer J, Wimberger P, Burchardi N, Kurzeder C, du Bois A, et al. Intraperitoneal treatment with the trifunctional bispecific antibody Catumaxomab in patients with platinum-resistant epithelial ovarian cancer: A phase IIa study of the AGO Study Group. Gynecol Oncol 2011; 123: 27-32. 15. Barnett T, Rubins J. Placement of a permanent tunneled peritoneal drain­age catheter for palliation of malignant ascites: A simplified percutaneous approach. J Vasc Intervent Radiol 2002; 13: 379-83. 16. Akinci D, Erol B, Ciftci T, Akhan O. Radiologically placed tunneled peritoneal catheter in palliation of malignant ascites. Eur J Radiol 2008; 80: 265-8. 17. Heiss M, Murawa P, Koralewski P, Kutarska E, Kolesnik O, Ivanchenko V, et al. The trifunctional antibody catumaxomab for the treatment of malignant ascites due to epithelial cancer: results of a prospective randomized phase II/III trial. Int J Cancer 2010; 127: 2209-21. research article CA19-9 serum levels predict micrometastases in patients with gastric cancer Tomaz Jagric1, Stojan Potrc2, Katarina Mis3, Mojca Plankl2, Tomaz Mars3 1 Department of Abdominal and General Surgery, University Medical Centre Maribor, Maribor, Slovenia 2 Institute of Pathophysiology, Faculty of Medicine, University of Ljubljana, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 204-211. Received 4 October 2014 Accepted 9 May 2015 Correspondence to: Tomaz Jagric, M.D., Ph.D., Department of Abdominal and General Surgery, University Medical Centre Maribor, Ljubljanska 5, Maribor 2000, Slovenia. Phone: +386 41 424 225; E-mail: tomaz.jagric@gmail.com Disclosure: No potential conflicts of interest were disclosed. Background. We explored the prognostic value of the up-regulated carbohydrate antigen (CA19-9) in node-negative patients with gastric cancer as a surrogate marker for micrometastases. Patients and methods. Micrometastases were determined using reverse transcription quantitative polymerase chain reaction (RT-qPCR) for a subgroup of 30 node-negative patients. This group was used to determine the cut-off for preoperative CA19-9 serum levels as a surrogate marker for micrometastases. Then 187 node-negative T1 to T4 patients were selected to validate the predictive value of this CA19-9 threshold. Results. Patients with micrometastases had significantly higher preoperative CA19-9 serum levels compared to pa­tients without micrometastases (p = 0.046). CA19-9 serum levels were significantly correlated with tumour site, tumour diameter, and perineural invasion. Although not reaching significance, subgroup analysis showed better five-year survival rates for patients with CA19-9 serum levels below the threshold, compared to patients with CA19-9 serum lev­els above the cut-off. The cumulative survival for T2 to T4 node-negative patients was significantly better with CA19-9 serum levels below the cut-off (p = 0.04). Conclusions. Preoperative CA19-9 serum levels can be used to predict higher risk for haematogenous spread and micrometastases in node-negative patients. However, CA19-9 serum levels lack the necessary sensitivity and specific­ity to reliably predict micrometastases. Key words: gastric cancer; micrometastases; CA19-9 Introduction In addition to local extent tumours, preoperative nodal staging is of the utmost importance when de­ciding upon lymphadenectomies in gastric cancer. Unfortunately, contemporary imaging modalities struggle with the modest sensitivities and specifici­ties when it comes to nodal staging.1 To make mat­ters even more challenging, the first metastases in early gastric cancer are usually in the form of small tumour-cell deposits, and the metastatic lymph nodes are often not enlarged.2 The average size of lymph nodes with micrometastases has been report­ed to be < 5 mm, which is below the size that can be reliably detected with preoperative imaging.2 Although the importance of micrometastases has been widely debated, there is some consensus on the prognostic relevance of micrometastases in lymph nodes.3-5 Due to their impact on long-term prognosis; many studies have searched for simple and reliable ways to detect micrometastases in pa­tients with gastric cancer. To date, the only way to determine the presence of micrometastases is the additional analysis of lymph nodes using immuno­histochemical or molecular methods.6-9 However, such elaborate and expensive methods used to de­tect micrometastases cannot be applied to clinical practice in their present form. Additional markers that can indicate the presence of such micrometas­tases will thus be of immense value. 205 Serum tumour markers have long been used for early detection and follow-up in patients with gastric cancer.10-15 Elevated serum levels of carbo­hydrate antigen 19-9 (CA19-9; or the sialyl-Lewis A determinant) have been the focus of investi­gations because of the reported association of CA19-9 with lymph-node metastases.14 CA19-9 is a tumour-associated carbohydrate determinant. Epigenetic silencing of the sialyltransferase gene early in tumour development leads to reduction in the production of the normally present disialyl-Lewis A determinant. This incomplete synthesis in tumour cells thus results in accumulation of the sialyl-Lewis A determinant (i.e., CA19-9). CA19-9 is a ligand for E-selectin, which is expressed on the surface of endothelial cells. These changes allow tumour cells to invade lymphovascular structures in the setting of low oxygen tissue tension during accelerated growth.16 Patients who show high ex­pressing levels of the CA19-9 antigen have been shown to be at greater risk of developing lymph-node and haematogenous metastases.14,16 The use of CA19-9 to indicate lymph-node metastases is, however, still controversial.10,12,13,17 The low sensi­tivity and specificity of CA19-9 does not allow for its use in the prediction of lymph-node metastases. Furthermore, CA19-9 serum levels are usually low in early gastric cancer, which precludes its use for the detection of early lymph-node metastases, or even micrometastasis. In our previous report, we demonstrated sig­nificant differences in the subclinical expression of serum levels of CA19-9 in patients with micro-metastases, compared to patients with negative lymph nodes.18 This led us to further explore these differences in patients with node-negative gastric cancer. To confirm the correlation of preopera­tive CA19-9 serum levels with micrometastases in the lymph nodes, we measured the preoperative CA19-9 serum levels in patients with and without lymph-node micrometastases. We then investigat­ed the correlation between micrometastases and preoperative CA19-9 serum levels to determine the cut-off level for micrometastases detection, along with the respective sensitivities and specificities. Finally, the prognostic value of this cut-off for CA19-9 serum levels was investigated for a group of patients with node-negative gastric cancer. Patients and methods Between 1992 and 2013, a total of 1,129 patients un­derwent surgery for gastric cancer at the University Clinical Centre Maribor, Slovenia. From these, only node-negative patients with complete clin­icopathological records and preoperative CA19-9 serum levels were included in this study. The inclusion criteria were for histologically confirmed node-negative adenocarcinoma of the stomach, D2 lymphadenectomy (as defined by the 3rd English edition of the Japanese Gastric Cancer Association guidelines18), and complete record of preoperative tumour marker levels. All surgical specimens underwent pathological examination according to the guidelines for gastric cancer of the International Union Against Cancer. Patients with missing values were excluded from further analy­sis. Thus, 187 patients were included in the final study group, with their preoperative CA19-9 cut­off levels tested for clinical significance. First, in a test group of 30 patients, we prospec­tively performed with reverse transcription quanti­tative polymerase chain reaction (RT-qPCR) analy­sis of sentinel lymph nodes for micrometastases, as described in our earlier reports.19,20 The preopera­tive differences in CA19-9 serum levels in these pa­tients were used to determine the cut-off value of the preoperative CA19-9 serum levels for further analysis. The study group of 187 patients was then used to determine the correlations between the preop­erative CA19-9 serum levels with tumour charac­teristics, its predictive significance, and the cut-off value. The mean follow-up was 37 ± 49 months (range, 2 days to 241 months). The patients were divided into two groups according to the derived cut-off value for the CA19-9 serum levels. Blood samples were obtained by peripheral venous puncture before surgery. CA19-9 serum levels were determined using commercial enzyme immunoassay kits (CA19-9; Dainabbot, Tokyo, Japan). The cut-off value was determined through receiver operating characteristics (ROC) analysis of the expression profiles from the RT-qPCR analysis for micrometastases. The sentinel lymph nodes were extracted as de­scribed in our previous reports.19,21 In brief, preop­erative risk assessment for the metastatic involve­ment of lymph nodes was carried out according to the Maruyama computer program, preoperative staging, and intraoperative dye navigation (Patente Blue V Dye; Guerbet Patent Blue V Sodium 2.5%; Guerbet, Roissy, France). The sentinel lymph nodes were harvested for RT-qPCR analysis. The total RNA was extracted using RNeasy Mini Plus kits (Qiagen, Hilden, Germany), and reverse transcribed with High Capacity cDNA Reverse TABLE 1. Patient demographic and tumor characteristics according to their positive Transcription kits (Applied Biosystems, Carlsbad, and negative Ca19-9 serum levels around the cut-off of 3.5 IU/ml CA, USA). Q-PCR was performed on an ABI Prism SDS 7500 PCR machine (Applied Biosystems), us­ing TaqMan chemistry in a 96-well format. TaqMan Gender [male (%)] 63 57 Universal PCR Master Mix (Applied Biosystems) Age (years ± SD) 64 ± 12.2 64 ± 11.9 and the following Gene Expression Assays (Applied Biosystems) were used: for CEACAM5 ASA (%) Hs 00237075_m1; for KRT20 Hs00300643_m1; and I 41.8 37.1 for GAPDH 4333764. Thirty-five cycles were select- II 37.3 37.1 ed as the Ct threshold values for CEACAM5 and III 20.9 25.7 CK-20 expression, as determined in our sensitivity and specificity studies.19 Lymphadenectomy (%) All continuous data are expressed as means ± D1 19.2 23.9 standard deviations, and the categorical data are ex­ D2 80.8 76.1 pressed in percentages. Continuous variables were Tumour site (%) compared with Student’s t tests, and .-squared Lesser curvature 33.3 38.6 tests were used for the comparison of discrete vari­ ables. Linear correlations were accessed by calcu- Greater curvature 38.9 40.4 lation of Pearson’s correlation coefficients. The Anterior wall 25.0 15.8 ROC curves were used to identify potential cut-off Posterior wall 1.4 2.6 values for the CA19-9 serum levels, along with the Circumferential 1.4 2.6 sensitivities and specificities. The Kaplan-Maier method was used for the survival analysis. Survival Differentiation (%) time was calculated from surgery to death or the Well 27.4 21.0 date of the last follow-up visit. The overall survival Moderate 25.8 33.0 differences between the groups were determined Poor 46.8 46.0 using log-rank tests. Cox regression models were Lauren (%) used to determine the factors related to the overall survival of node-negative patients. The final model Intestinal 63.9 47.2 was calculated with backward stepwise selection. Diffuse 19.7 31.5 A p value < 0.05 was defined as the limit of signifi- Mixed 16.4 21.3 cance. SPSS v.20 for Windows 8 was used for the Lymphangial invasion [yes (%)] 52.9 54.7 statistical analyses. The probability of lymph-node involvement was estimated with WinEstimate Vascular invasion[yes (%)] 7.3 11.1 (version 2.5; München, Germany). Perineural invasion[yes (%)] 15.7 14.4 T stage (%) 1 31.5 43.8 Results 2 38.4 28.9 Micrometastases were detected in eight patients 3 26.0 18.4 (26.7%) from the 30 histologically node-negative 4 4.1 8.8 patients. These patients with micrometastases had UICC (%) significantly higher preoperative CA19-9 serum Ia 31.5 45.6 levels (15.8 ±13 IU/ml) than those without micro- metastases (6.9 ± 9 IU/ml; p = 0.046). With the ROC Ib 38.4 28.9 analysis, the cut-off value for CA19-9 serum levels IIa 26.0 16.7 of 3.5 IU/ml was selected as a predictor for mi- IIb 1.4 5.3 crometastases deposits in lymph nodes. With this IIIb 2.7 3.5 threshold value, patients with micrometastases Tumour diameter (mm ± SD) 52 ± 33.8 50 ± 32.4 were determined with a sensitivity of 87.5% and a Number of extractedlymph nodes specificity of 50% (AUC, 0.724; p = 0.064). 21 ± 11.2 20 ± 10.7 (n ± SD) The mean CA19-9 serum level of the patients with node-negative gastric cancer was 27.8 ± 185 ASA = American Society of Anesthesiologists physical status classification system; UICC = Union for International Cancer Control IU/ml. Out of the 187 patients, 114 (61%) were above the threshold CA19-9 serum level of 3.5 IU/ ml. There was significant linear correlation between the preoperative CA19-9 serum levels and tumour sites (p = 0.035), tumour diameters (p = 0.012), and perineural infiltration (p = 0.007). There were signif­icant differences in the preoperative CA19-9 serum levels between patients with different tumour sites, as seen by one-way analysis of variance (ANOVA) tests. The patients with Bormann type IV tumour (i.e., whole stomach involvement) had the high­est preoperative CA19-9 serum levels (i.e., lesser curvature: 15.9 ± 48 IU/ml; greater curvature: 15.1 ± 52 IU/ml; anterior wall: 11.7 ± 20 IU/ml; whole circumference: 633.7 ± 1227 IU/ml; posterior wall: TABLE 2. Median survival rates of patients with T1 to T4 N0 tumours according to their positive and negative Ca19-9 serum levels around the cut-off of 3.5 IU/ml T1N0 Negative 121 ± 15.7 Positive 126 ± 12.2 T2N0 Negative 121 ± 13.9 Positive 89 ± 13.1 T3N0 Negative 103 ± 18 Positive 65 ± 12.4 T4N0 Negative 47 ± 18.9 Positive 18 ± 2.2 p = 0.427 p = 0.182 FIGURE 1. Survival of patients with T1 N0 (A), T2 N0 (B), T3 N0 (C) and T4 N0 (D) gastric cancer according to their positive and negative Ca19-9 serum levels around the cut-off of 3.5 IU/ml. TABLE 3. Results of the multivariate regression model analysis Perineural invasion 1.337 0.612 2.921 NS Tumour site 1.151 0.881 1.502 NS T stage 1.755 1.321 2.330 < 0.0001 Extracted lymph nodes 0.972 0.948 0.997 0.026 Preoperative Ca19-9 serum level 1 1.000 1.001 NS Ca19-9 cut-off (3.5 IU/ml) 1.045 0.528 2.068 NS NS = not significant p = 0.04 FIGURE 2. Survival of patients with T2 to T4 N0 gastric cancer according to their positive and negative Ca19-9 serum levels around the cut-off of 3.5 IU/ml. 9.7 ± 7 IU/ml; p < 0.0001). The preoperative CA19-9 serum levels of the patients with a tumour involv­ing the entire stomach were significantly greater than those where the tumour was confined to one location, irrespective of the TNM stage (p < 0.0001). Also, the patients with perineural infiltration had significantly higher preoperative CA19-9 serum levels (143.4 ± 526 IU/ml vs. 14.5 ± 43 IU/ml; p = 0.007). There were no statistically significant cor­relations between the cut-off value for the CA19-9 serum levels and the clinicopathological character­istics of the patients. These clinicopathological characteristics of the patients with CA19-9 serum levels above and be­low the cut-off of 3.5 IU/ml are shown in Table 1. Between these groups, there were no significant differences in age, gender, grade, Lauren histologi­cal type, TNM stage, tumour diameter, lymphangi­al infiltration, vascular infiltration, perineural inva­sion, extranodal infiltration, or extent of lymphad­enectomy distribution. The cumulative 5 year survival of the node-neg­ative patient group was 67.4% ± 4%, with a median survival of 130.9 months. The cumulative 5 year overall survival rates by T stage for T1, T2, T3, T4a and T4b were 77% ± 6%, 69% ± 7%, 56% ± 9%, 25% ± 22% and 31% ± 24%, respectively. There were no significant differences in the cumulative 5 year overall survival rates between groups with different cut-off values of the CA19­9 serum levels (CA19-9 negative group: 73% ± 6%; CA19-9 positive group: 63% ± 5%; p = 0.305). However, if we excluded the patients with stages T1a and T1b from the analysis, a significant dif­ference was seen between the overall survival of the patients with CA19-9 serum levels above and below our cut-off of 3.5 IU/ml (CA19-9 negative group: 72% ± 7%; CA19-9 positive group: 50% ± 8%; p = 0.04). Subgroup analysis failed to show signifi­cant differences in the 5 year overall survival rates for the individual stages of T1 to T4 between these CA19-9 negative and positive groups. Even so, the patients with stages T2 to T4 with CA19-9 serum levels above the set cut-off of 3.5 IU/ml had consist­ently worse overall survival rates than the patients below this cut-off value (Table 2, Figures 1, 2). The factors identified as significant predictors through univariate analysis were: preoperative CA19-9 serum level, tumour site, tumour diam­eter, T stage, number of extracted lymph nodes and the CA19-9 cut-off value. These were included in the Cox proportional hazard regression model. The multivariate analysis identified the significant prognostic factors in node-negative patients as T stage (hazard ratio, 1.755; 95% confidence inter­val, 1.321–2.33; p < 0.001) and number of extracted lymph nodes (hazard ratio, 0.972; 95% confidence interval, 0.948–0.997; p = 0.026) (Table 3). The procedures described in this study were in accordance with the Helsinki declaration. All pa­tients gave their written informed consent before being included in the present study. This study was approved by the National Ethics Committee (No. 153/02/0). Discussion According to previous reports, micrometastases in the lymph nodes have significant impact on patient survival.5,22-24 As the incidence of micrometastases 209 is said to be even as high as 30% in node-negative patients25-27, it appears that these patients should be correctly staged at least intraoperatively. While it might be possible to reliably detect microme­tastases with immunohistochemical or molecular techniques6-9, these techniques are time and labour intensive, and the results are usually available only after the operation. To identify a preoperative tool for micrometastases prediction, we explored the prognostic value of CA19-9 serum levels in node-negative patients. Since the introduction of CA19-9 serum levels in clinical practice, numerous publications have confirmed that elevated CA19-9 serum levels are a predictor for lymph-node metastases and indicate worse prognosis for patients with advanced gastric cancer.10-15 To the best of our knowledge, the preop­erative CA19-9 serum levels have never been used to predict micrometastases in patients with gastric cancer. As the up-regulated sialyl-Lewis A determi­nant (i.e., the CA19-9 antigen) in tumour cells has been shown to predispose patients with adenocar­cinoma and squamous cell carcinoma to haematog­enous metastases16, it can be seen that patients with elevated CA19-9 serum levels are at greater risk for micrometastatic lymph-node involvement. The aim of our study was to determine whether there is a correlation between early elevation of CA19-9 se­rum levels and the presence of micrometastases in patients with gastric cancer. We therefore studied the correlations of CA19-9 serum levels with the pathological properties of these tumours and the impact on the long-term survival of patients with node-negative gastric cancer. As previously reported by our group, a sig­nificant difference was noted in the preoperative subclinical (< 37 IU/ml) CA19-9 serum levels in patients with node-negative gastric cancer with micrometastases, compared to patients without micrometastases.18 Patients with micrometasta­ses were seen to have preoperative CA19-9 serum levels that were almost twice as high as those for patients without micrometastases. This observa­tion led us to believe that CA19-9 serum levels can be used as a predictor for micrometastatic lymph-node involvement in patients with node-negative gastric cancer. Cut-off values for CA19-9 serum levels as a marker for micrometastases were determined on a subgroup of 30 patients where their sentinel lymph nodes were subjected to RT-qPCR analysis in addi­tion to routine histology.19-21 For further analysis, the patients in the study group were divided into two groups according to the derived cut-off value of CA19-9 serum level of 3.5 IU/ml. This cut-off value was used as a surrogate marker for micro-metastases. Based on this cut-off, 61% of node-negative patients were shown to have elevated CA19-9 serum levels. Assuming that these patients were at high risk of harbouring micrometastases, the incidence of micrometastases was significantly higher than the 30% usually reported.24-27 In con­trast with the present study, T4 patients are usually excluded from micrometastases studies, due to the high proportion of early tumour recurrence in the peritoneal cavity.28,29 The T4 patients included in the present study with a probability of lymph-node deposits of > 80%, explain a much higher micro-metastatic involvement in the patient cohort in the present study compared to other reports. To determine whether CA19-9 serum levels were elevated in patients with micrometastases, a group of node-negative patients was retrospec­tively analysed. We selected patients from our da­tabase with TNM stages T1 to T4N0. As it would have been too time consuming to retrospectively look for micrometastases in the paraffin blocks of the lymph nodes of 187 patients, we instead searched for correlations of CA19-9 serum levels with the pathological features usually associated with node-negative patients with micrometastases, as indirect markers for the presence of micrometas­tases. In the present study, a significant correlation was observed between the preoperative CA19-9 se­rum levels and tumour size, perineural invasion, and type Borman IV tumours. All of these patho­logical features are signs of more aggressive and invasive tumour behavior30-35, and patients with tumours that show such features were found to be at greater risk for haematogenic spread and micro-metastases in the lymph nodes. To determine whether the cut-off value of the CA19-9 serum levels has a similar prognostic im­pact on node-negative patients as described for micrometastases, we compared the survival of the node-negative patients stratified into two groups according to the derived CA19-9 cut-off level. While there was no difference in the cumulative survival rate, a significant difference was found when the T1N0 patients were excluded. Patients with a tumour limited to the mucosa (T1a) have an excellent long-term survival rate, and when a D2 lymphadenectomy is performed, only a modest survival benefit is achieved compared to patients without micrometastases.28,29,36 Reports of the im­pact of micrometastases on survival are usually re­stricted to stages T1b, T2 and T3.28,29,36,37 These find­ings coincide with our data here that indicate a sur­ 210 vival benefit for the T2 to T4N0 patients with lower CA19-9 serum levels, and hence a lower probabil­ity of micrometastases. Assuming that preopera­tive CA19-9 serum levels are indeed a marker for micrometastases in node-negative patients, we can see that the stratification of patients according to our CA19-9 cut-off level had the same impact on survival as would be expected in patients with mi­crometastases. However, although this cut-off of CA19-9 serum levels of 3.5 IU/ml was identified as a significant predictor with univariate analysis, it failed to reach the limit of significance with multi­variate analysis. Thus, multivariate analysis iden­tified only T stage and the number of extracted lymph nodes as significant prognostic factors for overall survival. Although tumour markers have been extensive­ly used for the follow-up of oncological patients, their preoperative prognostic value remains to be determined. Based on our data, we show here that tumours with elevations in CA19-9 serum levels above 3.5 IU/ml share similar pathological proper­ties as seen in patients with micrometastases. This would identify the patients with higher likelihood for haematogenic dissemination. Whether CA19-9 serum levels can serve as a surrogate marker for micrometastases in patients with gastric cancer re­mains a matter of debate, but we have shown here that our CA19-9 cut-off of 3.5 IU/ml has prognostic significance in some node-negative patients, and in the future, this might be one of the preoperative screening tests that can be used to guide surgical and multimodal treatments of patients with node-negative gastric cancer. References 1. Kwee RM, Kwee TC. Imaging in assessing lymph node status in gastric can­cer. Gastric Cancer 2009; 12: 6-22. 2. Arai K, Iwasaki Y, Takahashi T. Clinicopathological analysis of early gastric cancer with solitary lymph node metastasis. Brit J Surg 2002; 89: 1435-7. 3. Yasuda K, Adachi Y, Shiraishi N, Inomata M, Takeuchi H, Kitano S. Prognostic effect of lymph node micrometastasis in patients with histologically node-negative gastric cancer. Ann Surg Oncol 2002; 9: 771-4. 4. Huang J, Xu Y, Li M, Sun Z, Zhu Z, Song Y, et al. The prognostic impact of occult lymph node metastasis in node-negative gastric cancer: A systemic review and meta-analysis. Ann Surg Oncol 2013; 20: 3927-34. 5. Cai J, Ikeguchi M, Kaibara N, Sakatani T. Clinicopathological value of immu­nohistochemical detection of occult involvement in pT3N0 gastric cancer. Gastric Cancer 1999; 2: 95-100. 6. Yanagita S, Natsugoe S, Uenosono Y, Arigami T, Arima H, Kozono T, et al. Detection of micrometastases in sentinel node navigation surgery for gastric cancer. Surg Oncol 2008; 17: 203-10. 7. Kubota K, Nakanishi H, Hiki N, Shimizu N, Tsuji E, Yamaguchi H, et al. Quantitative detection of micrometastases in the lymph nodes of gastric cancer patients with Real-time RT-PCR: A comperative study with immuno­histochemistry. Int J Cancer 2003; 105: 136-43. 8. Osaka H, Yashiro M, Sawada T, Katsuragi K, Hirakawa K. Is a lymph node detected by the dye-guided method a true sentinel node in gastric cancer? Clin Cancer Res 2004; 10: 6912-8. 9. Shimizu Y, Takeuchi H, Sakakura Y, Saikawa Y, Nakahara T, Mukai M, et al. Molecular detection of sentinel node micrometastases in patients with clinical N0 gastric carcinoma with real-time multiplex reverse transcription-polymerase chain reaction assay. Ann Surg Oncol 2012; 19: 469-77. 10. Ishigami S, Natsugoe S, Hokita S, Che X, Tokuda K, Nakajo A, et al. Clinical importance of preoperative carcinoembryonic antigen and carbohydrate antigen 19-9 levels in gastric cancer. J Clin Gastroenterol 2001; 32: 41-4. 11. Dilege E, Mihmanli M, Demir U, Özer K, Bostancu Ö, Kaya C, et al. Prognostic value of preoperative CEA and CA 19-9 levels in resectable gastric cancer. Hepatogastroenterology 2010; 57: 674-7. 12. Kodera Y, Yamamura Y, Torii A, Uesaka K, Hirai T, Yasui K, et al. The prognostic value of preoperative serum level of CEA and CA19-9 in patients with gastric cancer. Am J Gastroent 1996; 91: 49-53. 13. Mihmanli M, Dilege E, Demir U, Coskun H, Eroglu T, Uysalol MD. The use of tumor markers as predictors of prognosis in gastric cancer. Hepatogastroenterology 2004; 51: 1544-7. 14. Tsirlis TD, Kostakis A, Papastratis G, Masselou K, Vlachos I, Papachristodoulou A, et al. Predictive significance of preoperative serum VEGF-C and VEGF-D, independently and combined with Ca19-9, for the presence of malignancy and lymph node metastasis in patients with gastric cancer. J Surg Oncol 2010; 102: 699-703. 15. Mattar R, Alves de Andrade CR, DiFavero GM, Gama-Rodrigues JJ, Laudanna AA. Preoperative serum levels of CA 72-5, CEA, CA 19-9 and Alpha­fetoprotein in patents with gastric cancer. Rev Hosp Clin Fac Med S Paulo 2002; 57: 89-92. 16. Kannagi R. Carbohydrate antigen Sialyl Lewis a – Its pathophysiological significance and induction mechanism in cancer progression. Chang Gung Med J 2007; 30: 189-209. 17. Duraker N, Celik AN. The prognostic significance of preoperative serum CA 19-9 in patients with resectable gastric carcinoma: Comparison with CEA. J Surg Oncol 2001; 76: 266-71. 18. Japanese Gastric Cancer Association. Japanese gastric cancer treatment guidelines 2010 (ver. 3). Gastric Cancer 2011; 14: 113-23. 19. Jagric T, Potrc S, Ivanecz A, Horvat M, Plankl M, Mars T. Evaluation of focused sentinel lymph node RT-qPCR screening for micrometastases with the use of the Maruyama computer program. Eur Surg 2013; 45: 270-6. 20. Jagric T, Plakl M, Ivanecz A, Horvat M, Gajzer B, Grubic Z, et al. The prognos­tic value of micrometastases found intraoperatively in the first drainig lymph node in gastric cancer patients. Zdrav Vestn 2012; 81: 775-83. 21. Jagric T, Ivanecz A, Horvat M, Plankl M, Kavalar R, Potrc S, et al. Evaluation of a focused sentinel lymph node protocol in node-negative gastric cancer patients, Hepatogastroenterol 2013; 60: 1231-6. 22. Ishigami S, Natsugoe S, Tokuda K, Nakajo A, Higashi H, Watanabe T, et al. Clinical impact of micrometastasis of lymph node in gastric cancer. Am Surg 2003; 69: 573-7. 23. Nakajo A, Natsugoe S, Ishigami S, Matsumoto M, Nakashima S, Hokita S, et al. Detection and prediction of micrometastasis in the lymph nodes of patients with pN0 gastric cancer. Ann Surg Oncol 2000; 8: 158-62. 24. Sievert JR, Kestlmaier R, Busch R, Böttcher K, Roder JD, Müller J, et al. Benefits of D2 lymph node dissection for patients with gastric cancer and pN0 and pN1 lymph node metastases. Brit J Surg 1996; 83: 1144-7. 25. Saito H, Osaki T, Murakami D, Sakamoto T, Kanaji S, Ohro S, et al. Recurrence in early gastric cancer – Presence of micrometastases in lymph node nega­tive early gastric cancer patient with recurrence. Hepatogastroenterol 2007; 54: 620-4. 26. Otsuji E, Toma A, Kobayashi S, Okamoto K, Hagiwara A, Yamagishi H. Outcome of profilactic Radical lymphadenectomy with gastrectomy in pa­tients with early gastric carcinoma without lymph node metastases. Cancer 2000; 89: 1425-30. 27. Nakajo A, Natsugoe S, Ishigami S, Matsumoto M, Nakashima S, Hokita S, et al. Detection and prediction of micrometastases in the lymph nodes of patients with pN0 gastric cancer. Ann Surg Oncol 2001; 8: 158-62. 211 28. Fukagawa T, Sasako M, Ito S, Nakanishi H, Iinuma H, Natsugoe S. The prog­nostic signifficance of isolated tumor cells in the lymph nodes of gastric cancer patients. Gastric Cancer 2010; 13: 191-6. 29. Fukagawa T, Sasako M, Mann GB, Sano T, Katai H, Maruyama K, et al. Immunohistochemically detected micrometastases of the lymph nodes in patients with gastric carcinoma. Cancer 2001; 92: 753–60. 30. Cao L, Hu X, Zhang Y, Huang G. Adverse prognosis of clustered-cell versus single-cell micrometastases in pN0 early gastric cancer. J Surg Oncol 2011; 103: 53-6. 31. Kim JJ, Song KY, Hur H, Hur JI, Park SM, Park CH. Lymph node micrometasta­sis in node negative early gastric cancer. Eur J Surg Oncol 2009; 35: 409-14. 32. Chou HH, Kuo CJ, Hsu JT, Chen TH, Lin CJ, Tseng JH, et al. Clinicopatologic study of node-negative advanced gastric cancer and analysis of factors predicting its recurrence and prognosis. Am J Surgery 2013; 101: 623-30. 33. Iwasaki Y, Sasako M, Yamamoto S, Nakamura K, Sano T, Katai H, et al. Phase II study of preoperative chemotherapy with S-1 and Cisplatin followed by gastrectomy for clinically resectable type 4 and large type 3 gastric cancers (JCOG0210). J Surg Oncol 2013; 107: 741-5. 34. Kodera Y, Nakanishi H, Ito S, Mochizuki Y, Yamamura Y, Fujiwara M, et al. Detection of disseminated cancer cells in linitis plastic-type gastric carci­noma. Jpn J Clin Oncol 2004; 34: 525-31. 35. Endo K, Sakurai M, Kusumoto E, Uehara H, Yamaguchi S, Tsutsumi N, et al. Biological significance of localized type IV scirrhous gastric carcinoma. Oncol Letters 2012; 3: 94-9. 36. Miwa K, Miyazaki I, Sahara H, Fujimura T, Yonemura Y, Noguchi M, et al. Rationale for extensive lymphadenectomy in early gastric carcinoma. Brit J Cancer 1995; 72: 1518-24. 37. Maehara Z, Oshiro T, Endo K, Baba H, Oda S, Ichiyoshi Y, et al. Clinical sig­nificance of occult micrometastasis lymph nodes from patients with early gastric cancer who died of recurrence. Surgery 1996, 119: 397-402. case report Hepatic splenosis mimicking liver metastases in a patient with history of childhood immature teratoma Sara Jereb1, Blaz Trotovsek2, Breda Skrbinc3 1 Infectious Diseases Department, University Medical Centre Ljubljana, Ljubljana, Slovenia 2 Department of Abdominal Surgery, University Medical Centre Ljubljana, Ljubljana, Slovenia 3 Department of Medical Oncology, Institute of Oncology Ljubljana, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 212-217. Received 20 July 2014 Accepted 28 August 2014 Correspondence to: Sara Jereb, M.D., Infectious Diseases Department, University Medical Centre Ljubljana, Japljeva 2, 1000 Ljubljana, Slovenia. E-mail: sara.jereb@gmail.com Disclosure: No potential conflicts of interest were disclosed. Background. Hepatic splenosis is rare condition, preceded by splenectomy or spleen trauma, the term refers to nodular implantation of normal splenic tissue in the liver. In patients with history of malignancy in particular, it can be mistaken for metastases and can lead to unnecessary diagnostic procedures or inappropriate treatment. Case report. Twenty-two-year old male was treated for immature teratoma linked to undescended right testicle after birth. On regular follow-up examinations no signs of disease relapse or long-term consequences were observed. He was presented with incidental finding of mature cystic teratoma after elective surgery for what appeared to be left-sided inguinal hernia. The tumour was most likely a metastasis of childhood teratoma. Origin within remaining left testicle was not found. Upon further imaging diagnostics, several intrahepatic lesions were revealed. Based on radio-logic appearance they were suspicious to be metastases. The patient underwent two ultrasound guided fine-needle aspiration biopsies. Cytologic diagnosis was inconclusive. Histology of laparoscopically obtained tissue disclosed pres­ence of normal splenic tissue and led to diagnosis of hepatic splenosis. Conclusions. Though hepatic splenosis is rare, it needs to be included in differential diagnosis of nodular hepatic lesions. Accurate interpretation of those lesions is crucial for appropriate management of the patient. If diagnosis eludes after cytologic diagnostics alone, laparoscopic excision of nodular lesion is warranted before considering more extensive liver resection. Key words: hepatic splenosis; teratoma; metastases; laparoscopy Introduction Ectopic spleen tissue takes two forms, it is either congenital and presents as accessory spleens or an acquired condition, called splenosis. Splenosis occurs as un-encapsulated splenic tissue localized outside the spleen. It is a benign condition, most commonly linked to splenic trauma or splenecto­my. Post traumatic splenosis is believed to be a rare state; however, it is more likely only to be under-recognized. Patients are in fact most often asymp­tomatic and the majority of cases are diagnosed by coincidence.1 As a rule, there are multiple splenic tissue im­plants embedded in serous surfaces of abdominal cavity such as mesentery, omentum, surfaces of the colon or diaphragm. After penetrating abdominal trauma, extraperitoneal splenosis has also been reported in subcutaneous tissue, pleural cavity or pericardium.2-5 Rarely, splenic tissue can implant in paren­chyma of a visceral organ such as liver. In that case, the condition is defined as hepatic spleno­sis. Mechanism of splenic tissue spread is not completely understood. One of the hypotheses postulates invagination of splenic implants into 213 sub-capsular area of the liver after spleen trauma. Alternatively, deep-seated hepatic splenic nodules would results from the microembolisation via the splenic vein. Nodular lesions in liver parenchyma are non-specific on imaging and can mimic malig­nant as well as benign lesions.6 Exploratory lapa­roscopy is the least invasive method for reaching definitive diagnosis and is the most suitable, espe­cially in patients with history of malignant disease where liver metastases are suspected. Case report A 22-year old Caucasian male was presented after operative procedure due to left-sided inguinal her­nia, during which a cystic mass inside of hernial sac was revealed. Histology of the tumour disclosed it to be mature cystic teratoma. The patient was treated for immature teratoma with a prevalence of neuroepithelial components and with high mitotic activity 22 years prior and the tumour most likely originated from retained right testicle. Surgical procedure was performed on day 6 after birth. The tumour had perforated and was macroscopically removed. He received 3 cycles of chemotherapy with vincristine, actino­mycin D, cyclophosphamide and cisplatin in the adjuvant setting. On follow-up examinations there were no signs of relapse. At the age of 4 he under­went splenectomy after a motor vehicle accident. For the past year he had been treated for Henoch– Schönlein purpura with renal impairment, he was receiving methylprednisolone. After the operative procedure for hernia, pa­tient’s alpha-fetoprotein (AFP), Beta unit of human Chorionic Gonadotropin (Beta hCG) and Lactate dehydrogenase (LDH) levels were within normal ranges: AFP 2.2 kU/L (< 5.8), Beta hCG < 0.1 U/L (< 2.0), LDH 2.25 ukat/L (< 4.13). Additional labora­tory testing revealed thrombocyte count 491 *109 /L (140.340), neutrophil count 77.7% (40.75%), lym­phocyte count 17.3% (20.40%), eosinophil count 0.7% (1.6%), and sedimentation rate 29 mm/h (< 19). Electrolyte concentrations, liver function tests, LDH and thyroid hormones were within nor­mal limits. Imaging diagnostics were performed for dis­ease staging. Scrotal ultrasound revealed small left-sided hydrocele, and no suspicious lesions in left testicle. Left epididymis seemed appropri­ate. Computed tomography (CT) scan of thoracic organs demonstrated no signs of disease progres­sion. However, on abdominal CT scan two poorly demarcated areas in the 6th liver segment and un­der the capsule were seen in portal phase of con­trast enhancement (Figure 1). There was also small perihepatic oval shaped peritoneal solid lesion of same appearance. Liver size was normal. With a view to define perihepatic lesions, mag­net resonance imaging (MRI) with hepatospecific contrast medium (Gd-EOB-DTPA disodium, i.e. Primovist, Bayer Pharma AG) was performed. Five round lesions ranging from 0.7 to 2.6 cm in diameter were visible in 2nd, 6th segment and on the border of 6th and 7th segment. They were subcapsularly in liver parenchyma and on the surface of the liver. Lesions were hypointense in T1 weighted images (WI), slightly hyperintense in T2 WI, after adminis­tration of hepatospecific contrast medium enhanced during arterial phase, after that they remained hy­ pointense in the late phase images (Figures 2.4). Lesions were suspected to be metastases. The patient underwent two ultrasound guided fine-needle aspiration biopsies. Sonographically lesions were barely seen, mildly hyperechoic (Figure 5). Obtained samples were unfit to warrant a cytologic diagnosis. In order to verify suspicious lesions, laparo­scopic excision was carried out and intraopera­tive frozen section analysis evinced spleen tissue. 215 Histology of the obtained sample confirmed he­patic splenosis. Tumour, a coincidental finding at operative procedure in left inguinal region, was most likely a metastasis of childhood germ cell tumour. There were no signs of disease spread. Treatment of asymptomatic hepatic splenosis was not indicated. Discussion Hepatic splenosis is heterotopic autotransplanta­tion of splenic tissue, as a rule it is a consequence of spleen trauma or splenectomy carried out from other reasons. Ectopic splenic tissue in abdominal cavity is present in more than 60% of patients af­ter traumatic splenic rupture; however, isolated hepatic localization is described only in individu­al cases.6-10 The diagnosis is usually an incidental finding following diagnostics in the scope of an­other disease, as patients are most often asympto­matic. Mescoli et al. report an average time of 29 years between splenectomy and the liver nodules detection.6 The patient in our report underwent splenectomy 18 years before the hepatic splenosis was established. He was subjected to regular fol­low-up after the treatment for childhood immature teratoma, and intermittent abdominal sonography revealed no lesions in hepatic parenchyma. However, none of the imaging techniques is specific enough to identify hepatic splenosis; ul­trasound sensitivity is very poor, CT imaging is moderately sensitive and MRI has high sensitivity. Hypervascular nodular hepatic lesions are most commonly haemangioma, hepatic metastases, he­patic adenoma, focal nodular hyperplasia, hepa­tocellular carcinoma.11 Strictly peripheral lesions in hepatic parenchyma with peritoneal deposits in spleenless patient should warrant differential diagnosis of splenosis. With respect to childhood tumour, hepatic metastases and/or peritoneal dis­semination seemed a plausible differential diag­nostic option in presented case. The patient was subjected to operative treatment for abdominal tumour few days after birth. Tumour was linked to undescended right testicle and was histologi­cally diagnosed to be immature teratoma. Data shows a link between intraabdominal teratoma and cryptorchidism in children, also, tumour lo­calization at the annulus inguinalis profundus is believed to cause testicular retention.12 Mature teratoma presenting in our patient’s adulthood was considered to be a metastasis of primary childhood tumour and less likely metastatic germ cell tumour originating in left testicle. It is known that contralateral testicular tumour is more often found in patients with history of teratoma and in situ disgenesis is present in 9% of the patients.13 However, clinical examination, biochemistry and imaging excluded left testicle pathology with high probability. Considering differential diagnosis, nodular he­patic and perihepatic lesions could reflect metasta­ses of immature childhood teratoma as well as ma­ture adulthood teratoma. Immature teratomas are known to metastasize to the solid organs, includ­ing liver. Metastatic foci can contain histologically more mature elements than found in primary tu­mour. One of the reasons is retroconversion of me­tastases to differentiated mature teratoma under the influence of chemotherapy.14 Mature teratomas are usually asymptomatic and slow growing, 1.8 mm per year on average. That explains the long­time interval between primary tumor management after birth and finding the mature teratoma at the age of 22 in our case. Also, slow growth could ex­plain presence of nodular hepatic lesions, assessed as possible metastases. On the other hand, the ori­go of metastases could be the adulthood teratoma, as malignant alteration and metastasizing occur in 1 to 2% of mature teratomas.15 Differential diagnosis of hepatic splenosis is wide and indirect diagnostic procedures are unreliable as opposed to histologic evaluation. Hematological evaluation can be useful in assess­ing any persistence of functioning splenic tissue and the absence of Howell-Jolly bodies, Heinz bod­ies or pitted cells on blood smears may be helpful in diagnosing splenosis. However, sensitivity of the test is low, especially when there is only small amount of ectopic splenic tissue. There are no typical radiological features of in­trahepatic splenosis. Sonographic appearance is completely unspecific, similar to the current case. Hypoechoic, homogeneous, solid and well cir­cumscribed implants are described in literature, however, in our case lesions were sonographical­ly mildly hyperechoic.10 In contrast-enhanced CT scans, intrahepatic splenosis is generally revealed as round, oval, or lobular, well circumscribed, non-calcified and homogeneously enhancing. Before injection of contrast medium the implants are usu­ally hypodense or isodense to the liver. In the lit­erature, there are few published descriptions of hepatic splenosis on MRI.10,16-21 On MRI, the characteristics of splenosis are lim­ited to anecdotal cases that have found such lesions as homogeneous, of low signal intensity in T1 WI and moderately hyperintense in T2 WI. Sometimes hypointense thin layer of capsule around the lesion is found in T1 and T2 WI. In arterial or/and portal phase of enhancement lesions are mostly hyper-vascular and hypointense in delayed images.17 According to published reports intrahepatic splenosis is most commonly manifested as nodu­lar, solitary lesions, and ranging from 2 to 6 cm in size.6,8,10 Described characteristics are true in our case with the exception of the number of lesions. In contrast with presented case Mescoli et al. re­ported that solitary splenic nodules were found in 24 out of 27 patients with the hepatic splenosis. In only one patient more than three nodular lesions were found.6 Difference may stem from an under­estimation of the results based on radiological in­vestigations. In our case five intrahepatic implants were identified with MRI and two with CT, what is in concordance with multiple studies, which have shown that MRI is superior to CT in sensi­tivity and accuracy of detecting hepatic lesions.22 Upon ultrasonography the lesions were particu­larly indistinguishable and mildly hiperechoic. In the literature, all the lesions were described as hypoechoic. Splenosis is thought to be uncommon, but the incidence is probably underreported since the ma­jority of patients are asymptomatic. Distinguishing the aetiology of hepatic nodular lesions is impor­tant because it significantly alters therapeutic pro­cedures. Typical imaging modalities such as US, CT or MRI will not differentiate splenosis from other entities and a histologic specimen needs to be ob­tained to reach definitive diagnosis. Unfortunately, result of fine-needle aspiration biopsy can be in­conclusive as it was in presented case. On the other hand, laparotomy is an excessive operational pro­cedure with potential complications in patients with hepatic splenosis. We presented a case in 217 which hepatic splenosis has been confirmed by explorative laparoscopy. A laparoscopic approach is minimally invasive for the visualization of sus­pected intrahepatic masses, and allows access for potential liver biopsy or resection. Similar experi­ences have been described, but in only few pub­lished reports.9,23 Conclusions Due to the significant impact on treatment deci­sions intrahepatic splenosis must be considered in the diagnostic spectrum of nodular liver lesions, especially in patients with prior splenic trauma or surgery. References 1. Fleming CR, Dickson ER, Harrison EG Jr. Splenosis: autotransplantation of splenic tissue. Am J Med 1976; 61: 414-19. 2. Brewster DC. Splenosis. Report of two cases and review of the literature. Am J Surg 1973; 126: 14-9. 3. Bock DB, King BF, Hezmall HP, Oesterling JE. Splenosis presenting as a left renal mass indistinguishable from renal cell carcinoma. J Urol 1991; 146: 152-4. 4. Grantham JR, Clore FC. Subcutaneous splenosis. AJR Am J Roentgenol 1990; 154: 655. 5. Normand JP, Rioux M, Dumont M, Bouchard G, Letourneau L. Thoracic splenosis after blunt trauma: frequency and imaging findings. AJR Am J Roentgenol 1993; 161: 739-41. 6. Mescoli C, Castoro C, Sergio A, Ruol A, Farinati F, Rugge M. Hepatic spleen nodules (HSN). Scand J Gastroenterol 2010; 45: 628-32. 7. Livingston CD, Levine BA, Lecklitner ML, Sirinek KR. Incidence and function of residual splenic tissue following splenectomy for trauma in adults. Arch Surg 1983; 118: 617-20. 8. D’Angelica M, Fong Y, Blumgart LH. Isolated hepatic splenosis: first reported case. HPB Surg 1998; 11: 39-42. 9. Abu Hilal M, Harb A, Zeidan B, Steadman B, Primrose JN, Pearce NW. Hepatic splenosis mimicking HCC in a patient with hepatitis C liver cirrhosis and mildly raised alpha feto protein; the important role of explorative lapa­roscopy. World J Surg Oncol 2009; 7: 1. 10. Kang KC, Cho GS, Chung GA, Kang GH, Kim YJ, Lee MS, et al. Intrahepatic splenosis mimicking liver metastasis in a patient with gastric cancer. J Gastric Cancer 2011; 11: 64-8. 11. Toshikuni N, Shiroeda H, Ozaki K, Matsue Y, Minato T, Nomura T, et al. Advanced ultrasonography technologies to assess the effects of radiofre­quency ablation on hepatocellular carcinoma. Radiol Oncol 2013; 47: 224-9. 12. Doi O, Itoh F, Aoyama K. Mature teratoma arising in intraabdominal unde­scended testis in an infant with previous inguinal exploration: case report and review of intraabdominal testicular tumors in children. J Pediatr Surg 2002; 37: 1236-8. 13. Faure-Conter C, Rocourt N, Sudour-Bonnange H, Vérité C, Martelli H, Patte C, et al. Pediatric germ cell tumours. Bull Cancer 2013; 100: 381-91. 14. Kurata A, Hirano K, Nagane M, Fujioka Y. Immature teratoma of the ovary with distant metastases: favorable prognosis and insights into chemothera­peutic retroconversion. Int J Gynecol Pathol 2010; 29: 438-44. 15. Outwater EK, Siegelman ES, Hunt JL. Ovarian teratomas: tumor types and imaging characteristics. Radiographics 2001; 21: 475-90. 16. Gruen DR, Gollub MJ. Intrahepatic splenosis mimicking hepatic adenoma. AJR Am J Roentgenol 1997; 168: 725-6. 17. Tsitouridis I, Michaelides M, Sotiriadis C, Arvaniti M. CT and MRI of intraperi­toneal splenosis. Diagn Interv Radiol 2010; 16: 145-9. 18. Menth M, Herrmann K, Haug A, Raziorrouh B, Zachoval R, Jung CM, et al. Intra-hepatic splenosis as an unexpected cause of a focal liver lesion in a pa­tient with hepatitis C and liver cirrhosis: a case report. Cases J 2009; 2: 8335. 19. Choi GH, Ju MK, Kim JY, Kang CM, Kim KS, Choii JS, et al. Hepatic splenosis preoperatively diagnosed as hepatocellular carcinoma in a patient with chronic hepatitis B: a case report. J Korean Med Sci 2008; 23: 336-41. 20. Nakajima T, Fujiwara A, Yamaguchi M, Makiyama A, Wakae T, Fujita K, et al. Intrahepatic splenosis with severe iron deposition presenting with atypical magnetic resonance images. Intern Med 2008; 47: 743-6. 21. Imbriaco M, Camera L, Manciuria A, Salvatore M. A case of multiple intra­abdominal splenosis with computed tomography and magnetic resonance imaging correlative findings. World J Gastroenterol 2008; 14: 1453-5. 22. Marcan M, Pavliha D, Music MM, Fuckan I, Magjarevic R, Miklavcic D. Segmentation of hepatic vessels from MRI images for planning of electropo­ration-based treatments in the liver. Radiol Oncol 2014; 48: 267-81. 23. Liu K, Liang Y, Liang X, Yu H, Wang Y, Cai X. Laparoscopic resection of isolated hepatic splenosis mimicking liver tumors: case report with a literature re­view. Surg Laparosc Endosc Percutan Tech 2012; 22(5): e307-11. research article Treatment of nasopharyngeal carcinoma using simultaneous modulated accelerated radiation therapy via helical tomotherapy: a phase II study Lei Du1,2, Xin Xin Zhang3, Lin Chun Feng1, Jing Chen1, Jun Yang4, Hai Xia Liu1, Shou Ping Xu1, Chuan Bin Xie1, Lin Ma1 1 Department of Radiation Oncology, Chinese PLA General Hospital, Beijing, China 2 Department of Radiation Oncology, Hainan Branch of Chinese PLA General Hospital, Haitang Bay, Sanya, China 3 Department of Otorhinolaryngology, Chinese PLA General Hospital, Beijing, China 4 Department of Oncology, the First Affiliated Hospital of Xinxiang Medical University, Xinxiang, Henan, China Radiol Oncol 2016; 50(2): 218-225. Received 31 August 2015 Accepted 9 December 2015 Correspondence to: Lin Ma, M.D., Department of Radiation Oncology, Chinese PLA General Hospital, 28 Fuxing Road, Beijing 100853, China. E-mail: malinpharm@sina.com Disclosure: No potential conflicts of interest were disclosed. The first and second authors contributed equally to this article Background. The aim of the study was to evaluate short-term safety and efficacy of simultaneous modulated acceler­ated radiation therapy (SMART) delivered via helical tomotherapy in patients with nasopharyngeal carcinoma (NPC). Methods. Between August 2011 and September 2013, 132 newly diagnosed NPC patients were enrolled for a pro­spective phase II study. The prescription doses delivered to the gross tumor volume (pGTVnx) and positive lymph nodes (pGTVnd), the high risk planning target volume (PTV1), and the low risk planning target volume (PTV2), were 67.5 Gy (2.25 Gy/F), 60 Gy (2.0 Gy/F), and 54 Gy (1.8 Gy/F), in 30 fractions, respectively. Acute toxicities were evaluated ac­cording to the established RTOG/EORTC criteria. This group of patients was compared with the 190 patients in the retrospective P70 study, who were treated between September 2004 and August 2009 with helical tomotherapy, with a dose of 70-74 Gy/33F/6.5W delivered to pGTVnx and pGTVnd. Results. The median follow-up was 23.7 (12-38) months. Acute radiation related side-effects were mainly problems graded as 1 or 2. Only a small number of patients suffered from grade 4 leucopenia (4.5%) or thrombocytopenia (2.3%). The local relapse-free survival (LRFS), nodal relapse-free survival (NRFS), local-nodal relapse-free survival (LNRFS), distant metastasis-free survival (DMFS) and overall survival (OS) were 96.7%, 95.5%, 92.2%, 92.7% and 93.2%, at 2 years, respectively, with no significant difference compared with the P70 study. Conclusions. SMART delivered via the helical tomotherapy technique appears to be associated with an accept­able acute toxicity profile and favorable short-term outcomes for patients with NPC. Long-term toxicities and patient outcomes are under investigation. Key words: nasopharyngeal carcinoma; simultaneous modulated accelerated radiation therapy; helical tomother­apy; acute toxicities, clinical outcome Introduction Nasopharyngeal carcinoma (NPC) is a kind of head and neck cancer with a good prognosis, and can be cured by radiation therapy especially inten­sity-modulated radiation therapy (IMRT) alone or in combination with chemotherapy and/or anti-ep­ithelial growth factor receptor (anti-EGFR) mono­clonal antibody (Mab) treatment.1 The curative ef­fect and radiation injury are closely related to radi­ 219 ation techniques. Simultaneous modulated acceler­ated radiation therapy (SMART) has been clinically confirmed as safe and effective, and widely used in the treatment of NPC.2 This technique can simulta­neously deliver different doses to different targets, and improve local control through increasing the fraction dose and shortening the overall treatment time (OTT), so as to reduce post-procedure acceler­ated repopulation of tumor cells. Helical tomotherapy (HT) is believed to excel in realizing the function of SMART. Providing bet­ter dose conformity and uniformity, HT could im­prove local control with less radiation damage. The first HT unit in China was installed in September 2007 at our center; and by December 2014, nearly 500 NPC patients had received treatment. The pre­scription dose of 70 Gy was given to the target vol­ume in 33 fractions (2.12 Gy per fraction) in a previ­ous study (P70 study) conducted by our team, and the clinical efficacy was satisfactory with an accept­able safety profile. The local relapse-free survival (LRFS), nodal relapse-free survival (NRFS), local-nodal relapse-free survival (LNRFS), distant me­tastasis-free survival (DMFS) and overall survival (OS) were 96.1%, 98.2%, 94.2%, 95.5% and 91.4%, at 2 years, respectively.3 The present phase II study (P67.5) was based on P70, starting from September 2011. In P67.5 we shortened the treatment time to 6 weeks by designing a hypofractionated regimen with a total dose of 67.5 Gy (2.25 Gy/F). By com­parison with the P70 study, we evaluated the feasi­bility and short-term outcomes of this new hypof­ractionated regimen. Methods Eligibility criteria P67.5 is a single-center, prospective, phase II clini­cal study, with a registration code of ChiCTR­ONC-14004895. The research ethics board of the Chinese PLA General Hospital approved the study with an official number of S2014-048-01, and all eli­gible patients provided informed consent in writ­ten form. Inclusion criteria were as follows: histologically proven type I and II NPC according to World Health Organization (WHO) criteria; stage I–IVa accord­ing to the Union for International Cancer Control (UICC) 2002 Staging System; aged between 15 and 75 years; Karnofsky performance status score . 70; white blood cell count . 3,500/µL, platelet count . 100,000/µL, serum creatinine concentration < 133 umol/L, and liver transaminase level < 2.0 times of the upper normal value. Exclusion criteria were as follows: distant metastasis; concomitant diseases (heart disease, tuberculosis, etc.) that interfere with the completion of treatment, increase incidence of adverse reactions or influence the prognosis; withdrawal during the treatment or violation of the protocol due to any factors; diagnosed with or treated for other malignances. Patient characteristics Between August 2011 and September 2013, 132 newly diagnosed non-metastatic NPC patients were included in the study. There were 95 males and 37 females. The median age was 47 years old. All patients underwent nasopharyngeal and skull base magnetic resonance imaging (MRI), chest computed tomography (CT), endoscopic evalu­ation, complete blood counts, hepatic and renal function tests, neck and abdomen ultrasound, and bone scans. Positron emission tomography (PET) was optional. Clinical stage was practiced accord­ing to the UICC 2002 staging system (Table 1). We compared the preliminary results of the P67.5 study with the retrospective P70 study, in which a dose of 70–74 Gy (2.12–2.24 Gy per frac­tion) was delivered to the primary tumor (pGT-Vnx) and metastatic nodes (pGTVnd), 60–62.7 Gy (1.82–1.89 Gy per fraction) to the high risk plan­ning target volume (PTV1) and 52–56 Gy (1.63–1.70 Gy per fraction) to the low risk planning target vol­ume (PTV2), in 33 fractions.3 Table 2 summarizes patients’ characteristics in the two studies. Radiation therapy Patients were placed in the supine position and the head and neck immobilized with a thermoplastic mask. Plain and enhanced CT images with 3-mm slice thickness were taken for treatment planning then transmitted to the Pinnacle3 8.0 workstation and fused. Enhanced CT, MRI or PET images were TABLE 1. Distributions of patients in P67.5/P70 study according to the Union for International Cancer Control (UICC) 2002 staging system T1 6/16 13/27 11/15 3/3 33/61 T2 3/13 15/24 23/22 3/2 44/61 T3 2/8 15/11 18/18 3/3 38/40 T4 2/3 3/10 11/11 1/4 17/28 Total 13/40 46/72 63/66 10/12 132/190 FIGURE 1. Different survival rates for patients in the P67.5 study. TABLE 2. Patients’ characteristics Age (median) 15–75 (47) 10–81 (44) 0.527 Gender Male 95 72.0 144 75.8 0.441 Female 37 28.0 46 24.2 Region Northern China 110 83.3 159 83.7 0.933 Southern China 22 16.7 31 16.3 KPS 90-100 105 79.5 133 70.0 0.055 70-80 27 20.5 57 30.0 Pathology WHO type I 2 1.5 3 1.6 0.964 WHO type II 130 98.5 187 98.4 UICC 2002 Stage I 6 4.5 16 8.4 II 31 23.5 64 33.7 0.045 III 68 51.5 71 37.4 IVa-b 27 20.5 39 20.5 KPS = Karnofsky performance status; UICC = Union for International Cancer Control; WHO = World Health Organization used as a guide for target contours. Target nam­ing and delineation were consistent with the P70 study3, and CT images together with the contour objects created by the physicians were trans­ferred to Hi Art TomoTherapy 2.2.4.1 workstation. Physicists in the same group designed and verified the treatment plans. The three main parameters of field width, pitch, and modulation factor were set to the same values as in the P70 study. During HT treatment, all patients underwent megavoltage computed tomography (MVCT) im­aging everyday to rectify setup errors. The range of the CT scans typically included the central area of the whole target volume, ensuring that crystals were avoided. Automated and manual registration of the MVCT images with the planning CT images was based on bone and tissue anatomy. The planned D95 was 67.5 Gy for pGTVnx and pGTVnd, 60 Gy for PTV1 and 54 Gy for PTV2, in 30 fractions. No more than 5% of the PTV received more than 110% of the prescribed dose. The dose-volume constraints for OARs (organs at risk) were the same as the P70 study.3 Biological effective dose (BED) is calculated with linear quadratic (LQ) radiobiological model: BED = nd × [1 + d/(./ß)].4 In the formula, “n” represents the number of fractions and “d” fraction dose. The ./ß value of tumor tissue or early response normal tissues is 10 Gy and that of late response normal tissues is 3 Gy or 5 Gy. If the impact of overall treat­ment time (OTT) and tumor proliferation is consid­ered, the adjusted formula is BED = nd × [1 + d/ (./ß)] -./. × (T -Tk).5 The “./.” equals 0.6. “T” and “Tk” represent OTT (including weekends) and 7 days, respectively. Chemotherapy and anti-EGFR monoclonal antibody (Mab) treatment In this study, patients at stage III or IV (including stage II with lymph node metastasis) generally underwent neoadjuvant chemotherapy plus con­current chemotherapy. Two cycles of neoadjuvant chemotherapy were routinely used, some patients with stage III and IV or whose tumor volume re­duced less than 30% had additional 1-2 cycles. One hundred and one patients underwent 1–4 cycles of neoadjuvant chemotherapy with DP (docetaxel 75 mg/m2, d1, and cisplatin 75 mg/m2, d1, every 3 weeks) according to the primary tumor size or chemotherapy response. In accordance with the physical condition, clinical staging, treatment tol­erance, 115 cases underwent two patterns of con­current chemotherapy: 1) cisplatin 80 mg/m2, d1, 221 every 3 weeks; 2) cisplatin 60 mg/m2 and docetaxel 60 mg/m2, d1, every 3 weeks. Concurrent anti-EG­FR Mab treatment (cetuximab with a loading dose of 400 mg/m2 and then 250 mg/m2 or nimotuzum­ab 200 mg every week) was used in 45 patients. Adjuvant DP chemotherapy as used in the neo­adjuvant setting was administered in 68 patients (range 1–4 cycles, median 1.93 cycles). TABLE 3. BED of the two SMART regimens (Gy) Tumor OTT disregarded (./ß= 10Gy) 82.7 84.8 Tumor OTT taken into account (./ß= 10Gy) 62.9 62.0 Normal tissue (./ß= 5Gy) 97.9 99.7 Normal tissue (./ß= 3Gy) 118.1 119.5 Statistical analysis and follow-up BED = biological effective dose; OTT = overall treatment time; SMART = simultaneous modulated accelerated radiation therapy Acute side-effects were evaluated weekly and peak toxicities were recorded. Acute and late side-ef­fects were identified according to the established RTOG/EORTC criteria.6 The preliminary response TABLE 4. Dosimetric data of organs at risk was evaluated 1–3 months after the end of radia­ tion therapy based on the Response Evaluation Criteria in Solid Tumors (RECIST) Version 1.1.7 Patients received follow-up examinations includ­ing nasopharyngeal and skull base MRI, nasopha­ryngoscopy, neck ultrasound, etc., to evaluate the therapeutic effects every 3 months during the first year, and then every 6 months afterwards. By the end of October 2014, the median follow-up period was 23.7 (12–38) months with a follow-up rate of 100%. Survival analysis was performed with Kaplan-Meier method and Log-rank test was used to evaluate the differences between the 2 studies. Comparison of rates and means between the two groups was performed by Pearson .2 test and t test, respectively. A two-sided value of p < 0.05 was considered significant. The analyses were execut­ed with SPSS 19.0 (Statistical Product and Service Solutions Inc., Chicago, IL). Results BED and dosimetric analyses The prescription dose in the study for tumor targets was 67.5 Gy (2.25 Gy × 30F) with a BED of 82.7 Gy. If the impact of OTT was considered, the adjusted BED would be 62.9 Gy, 0.9 Gy higher than that of the P70 study, and would theoretically result in better tumor control. For normal tissues, radiation doses to both early and late response tissues were lower in this study than in the P70 study (Table 3). The mean dose (Dmean) to pGTVnx, pGTVnd, PTV1 and PTV2 was 70.2 Gy, 70.1 Gy, 64.9 Gy and 56.7 Gy, respectively (Table 3). Except the Dmean of inner ears and Dmean of both parotid glands, the dose delivered to OARs which generally met Beam-on time (s) Couch travel (cm) pGTVnx Dmean pGTVnd Dmean PTV1 Dmean PTV2 Dmean Brainstem Dmax Spinal cord Dmax Optic nerve Dmax Left Right Eyeball Dmax Left Right Lens Dmax Left Right TMJ Dmean Left Right Inner ear Dmean Left Right Parotid gland Dmean Left Right Oral cavity Dmean L-E-T Dmean 413.8 (336.0-521.7) 21.4 (18.0-27.0) 70.2 (69.2-72.6) 70.1 (69.2-72.7) 64.9 (63.1-67.3) 56.7 (55.7-59.8) 51.1 (35.9-69.1) 40.6 (35.2-51.1) 29.0 (3.9–70.5) 28.3 (4.6–70.8) 19.4 (4.0–38.9) 19.1 (5.3–38.8) 3.2 (2.0–5.3) 3.2 (2.2–8.3) 33.7 (22.6–60.4) 33.1 (22.5–64.7) 45.4 (27.4–67.1) 44.7 (26.3–61.7) 30.8 (25.2–39.9) 30.7 (22.9–65.2) 34.2 (26.6-42.0) 32.7 (24.2-38.8) 455.8 (358.0-696.0) 0.674 22.6 (17.0-28.7) 0.000 72.3 (70.4-75.6) 0.000 72.3 (70.1-75.6) 0.000 64.6 (62.1-70.5) 0.083 57.4 (54.7-61.7) 0.000 54.5 (41.6–71.9) 0.000 41.5 (33.7–51.8) 0.003 38.3 (9.7–72.2) 0.000 39.3 (9.2–72.9) 0.000 29.6 (10.0–65.4) 0.000 29.6 (11.2–57.7) 0.000 4.1 (2.2–8.1) 0.000 4.1 (2.2–8.3) 0.000 38.7 (22.9–58.5) 0.000 38.2 (21.1–51.8) 0.000 43.1 (12.3–58.0) 0.055 44.4 (11.6–65.2) 0.815 31.2 (23.8–55.1) 0.334 31.0 (22.0–47.9) 0.636 38.8 (11.5–50.2) 0.000 38.7 (19.1–49.6) 0.000 the established constrains were significantly lower Dmean = mean dose (Gy); Dmax = maximum dose (Gy); L-E-T = Larynx-esophagus-trachea; pGTVnd = positive lymph nodes; pGTVnx = prescription doses delivered to the gross tumor volume; in the P67.5 study than in the P70 study (Table 4). TMJ = Temporomandibular joint; TABLE 5. Acute toxicities of normal organs [n (%)] Skin reaction 6 (4.5) 7 (3.7) 92 (69.7) 137 (72.1) 27 (20.5) 37 (19.5) 7 (5.3) 9 (4.7) 0 (0.0) 0 (0.0) 0.961 Mucositis 2 (1.5) 4 (2.1) 54 (40.9) 72 (37.9) 64 (48.5) 108 (56.8) 12 (9.1) 6 (3.2) 0 (0.0) 0 (0.0) 0.100 Xerostomia 4 (3.0) 9 (4.7) 33 (25.0) 100 (52.6) 95 (72.0) 81 (42.6) 0 (0.0) 0 (0.0) 0 (0.0) 0 (0.0) 0.000 Pharyngitis-esophagitis 0 (0.0) 7 (3.7) 51 (38.6) 83 (43.7) 79 (59.9) 99 (52.1) 2 (1.5) 1 (0.5) 0 (0.0) 0 (0.0) 0.072 Leucopenia 29 (22.0) 86 (45.3) 32 (24.2) 42 (22.1) 39 (29.6) 50 (26.3) 26 (19.7) 10 (5.3) 6 (4.5) 2 (1.0) 0.000 Anemia 66 (55.0) 175 (92.1) 44 (33.4) 14 (7.4) 18 (13.6) 1 (0.5) 4 (3.0) 0 (0) 0 (0.0) 0 (0) 0.000 Thrombocytopenia 103 (78.0) 180 (94.7) 16 (12.1) 7 (3.7) 5 (3.8) 2 (1.1) 5 (3.8) 1 (0.5) 3 (2.3) 0 (0) 0.000 Acute and late side-effects All patients completed radiation therapy but one who underwent 27 fractions because of severe gastrointestinal side-effects. One hundred and twenty-four cases finished their radiation therapy in 6 weeks, and radiation therapy was interrupted for 10.9 days on average in 7 patients because of grade 3 acute pharyngitis-esophagitis or hemato­logic toxicity. Acute radiation related side-effects were mainly problems graded as 1 or 2 with skin, oral mucosa, salivary glands, and pharynx-esoph­agus. Grade 3 skin toxicities were noted in 7 cases, mucositis in 12 and pharyngitis-esophagitis in 2. Some patients who received neoadjuvant and/or concurrent chemotherapy suffered from different degrees of hematologic toxicities. Distribution of acute side-effects is shown in Table 5. The differ­ences were statistically significant between the in­cidences of xerostomia and hematologic toxicities of the two studies. At the end of radiation therapy, there was an average weight loss by 10.6%, ranging from 0% to 21.4%. Late toxicities generally appeared 3 months af­ter radiation therapy and the most common one was xerostomia. Although patients generally had less dry feeling as time passed by and 24 patients had no signs of late xerostomia at all, there were 102 and 6 cases suffering from grade 1 and 2 xe­rostomia during the follow-up, respectively. The sense of taste diminished in 6 patients and was lost completely in 1 patient. Forty-one patients had au­dition test abnormal on one side, 30 of whom had no obvious clinical symptoms; however, 12 and 5 cases appeared to have grade 1 and 2 hearing loss, respectively. Fifteen cases developed otitis media that needed surgical treatment. Seventeen patients had a difficulty in opening mouth, and 3 of them had a mouth opening less than a one-finger width. Increased tooth sensitivity occurred in 30 patients; gingival recession in 16 patients; tooth fracture or loss in 10 patients. One 39-year-old female had a menstrual disorder and one female patient had hy­pothyroidism requiring medical treatment. Short-term outcomes and patterns of failure At a median time of 1.5 months (at least one month and no more than 3 months) after the end of radia­tion therapy, evaluation of primary tumors showed that 49 patients had complete responses (CR), 71 partial responses (PR), and 12 stable disease (SD); evaluation of involved nodes in 113 patients showed 42 CR, 62 PR, and 9 SD, with an effective rate of 100%. Sixteen patients suffered from treatment fail­ure during the follow-up, including 3 local recur­rences (2 intra-target recurrences and 1 marginal recurrence), 4 regional recurrences and 9 distant metastases. In the patients with local recurrence, the T3N2M0 case received re-irradiation alone, the T3N0M0 case underwent re-irradiation with concurrent chemotherapy, and the T3N1M0 case refused salvage treatment. All these three patients died of bleeding with a mean survival time of 7.7 (3–10) months from recurrence to death. Among the regional recurrence patients, 3 had a neck node recurrence and 1 had an ipsilateral parotid me­tastasis; these patients underwent re-irradiation, chemotherapy, concurrent chemo-radiotherapy and brachytherapy respectively and were all alive throughout the follow-up. Distant metastasis was the most common failure pattern and the most 223 common distant organs involved were liver (4 cas­es), lung (2 cases), bone (2 cases), and liver-lung (1 case). Seven of the 9 cases received chemotherapy, of whom 2 had also concurrent Anti-EGFR Mab treatment (4 cases died, 3 cases alive); and the other 2 cases had no salvage treatment and died in 4 and 7 months, respectively (Table 6). The local relapse-free survival (LRFS), nodal relapse-free survival (NRFS), local-nodal relapse-free survival (LNRFS), distant metastasis-free survival (DMFS) and over­all survival (OS) were 96.7%, 95.5%, 92.2%, 92.7% and 93.2%, at 2 years, respectively, with no signifi­cant difference compared with the P70 study. Discussion It is generally believed that, in order to obtain a satisfactory local control, the prescribed dose of ra­diation therapy (RT) in NPC should exceed 64 Gy8, but it does not mean higher doses lead to higher local control rate (LCR). In contrast, clinical and radiobiological evidence has proved OTT as an important factor impacting curative effect of RT. Some tumor cells exhibited accelerated repopula­tion during the late period of RT. As the treatment continued, the probability of proliferation of tumor stem cells increased and the total dose should com­pensate for the “wasted dose” in every extra day because of accelerated repopulation of stem cells (0.6 Gy/d, equal to ./. value).5,9-11 At the same time, a higher prescribed dose would cause higher irra­diation to OARs and increase the risk of radiation related injury. When we prescribe the specific dose in radical RT for NPC with conventional fractionation, in addition to considering tumor extension or size, we must also pay attention to the impact of frac­tion size and OTT, so that the proper fraction dose can be chosen to avoid not only increased injury of late response normal tissues but also extended OTT. That was why a dose of more than 70 Gy was not recommended in conventionally fractionated RT for NPC. The limitation of conventionally frac­tionated RT in NPC seemed to have been solved by hyperfractionated radiation therapy which was however difficult to carry out in the past due to technical limitations of the two-dimensional conventional or three-dimensional conformal ra­diation therapy. After 20 years of continuous de­velopment and improvement, IMRT could solve the above problem through SMART which could deliver different doses to different targets accord­ing to the radiosensitivity (./ß value) of OARs and TABLE 6. Patients with treatment failure 1. T1N2M0 6 Bone CT Dead 17 2. T3N3bM0 7 Liver CT Dead 14 3. T2N2M0 8 Lung CT+AT Living 14 4. T1N2M0 9 Bone CT+AT Dead 12 5. T3N2M0 10 Lung - Dead 17 6. T1N2M0 10 Liver CT Living 16 7. T3N2M0 10 Local RT Dead 20 8. T3N1M0 12 Liver CT Dead 31 9. T3N2M0 13 Nodal RT Living 37 10. T1N3bM0 13 Nodal BT Living 26 11. T4N0M0 14 Liver - Dead 18 12. T3N1M0 21 Local - Dead 24 13. T3N1M0 22 Liver & Lung CT Living 33 14. T3N0M0 23 Local CRT Dead 33 15. T3N2M0 23 Nodal CT Living 27 16. T2N2M0 24 Nodal CRT Living 37 AT = anti-EGFR Mab therapy; BT = brachytherapy; CRT = concurrent chemoradiotherapy.CT = chemotherapy; RT = radiation therapy; * The time from diagnosis. boost doses to tumor targets within a limited time, so as to improve the efficacy with less normal tis­sue damage, and increase the gain ratio of RT. A number of clinical studies of SMART in NPC have been reported, but prospective studies were lacking. Table 7 listed the results of some prospec­tive studies with fractionation patterns, LCR, etc. It could be seen that fraction dose ranged from 2.12 to 2.4 Gy, and the total BED based on prescription doses all exceeded 80 Gy. An adjusted BED was ob­tained between 60 and 70 Gy. The 2–4 year LCR was beyond 90% except the 88% reported by Lee et al., probably because of a small sample size and a high proportion (95% of patients) of advanced disease.12 The RTOG 0225 study was a classic multi-center study which led the 70 Gy/33F SMART regimen to be used as the standard RT of NPC with a LCR of 92.6% at 2 years.14 Our center began to conduct P70 study with the same fractionated regimen in September 2007 when the HT system was first in­troduced into China; and achieved good outcomes with the 2-year LRFS of 96.1%.3 In the present study which was based on the P70 study, the fraction dose increased from 2.17 Gy to 2.25 Gy and the adjusted BED to tumor targets got higher, while BED to nor­mal tissues was reduced. Xiao et al.15 conducted a TABLE 7. Summary of reported prospective studies on simultaneous modulated accelerated radiation therapy (SMART) for nasopharyngeal carcinoma (NPC) Lee SW (2005)12 20 8 (40) 18 (90) 30 72 2.4 89.3 69.5 88.0 (2-y) Lin SJ (2009)13 323 260 (80.5) 293 (90.7) 30 / 31 66 / 69.8 2.2 / 2.25 80.5 / 85.4 60.7 / 63.8 95.0 (3-y LRFS) RTOG0225 (2009)14 68 23 (33.8) 50 (73.5) 33 70 2.12 84.8 62.0 92.6 (2-y) Xiao WW (2011)15 81 81 (100) 56 (69.1) 30 68 2.27 83.4 63.6 94.9 (3-y) Bakst RL (2011)16 25 16 (64) 20 (80) 30 70.2 2.34 86.6 66.8 91.0 (3-y) Wang RS (2013)17 300 214 (71.3) 277 (92.3) 30-32 68-72 2.25-2.27 83.4-88.2 63.6-66.0 94.0 (4-y) Author (2014)3 190 68 (35.8) 150 (78.9) 33 70 2.12 84.8 62.0 96.1 (2-y LRFS) Current study 132 55 (41.7) 119 (90.2) 30 67.5 2.25 82.7 62.9 96.7 (2-y LRFS) *: ./ß= 10Gy; OTT = overall treatment time; LCR = local control rate; LRFS = local relapse-free survival; y = year phase II study in T3-4 patients using a 68 Gy/33F regimen similar to ours and the 3-year LCR reached 94.9%. In the study of Wang et al.17, the 68 Gy/33F regimen was still applied although up to 83% of the patients had locally advanced disease; LCR re­mained to be 94%. In this study, the 2-year LRFS and NRFS achieved 96.7% and 95.5%, respectively, without difference compared with the P70 study, in which LRFS and NRFS being 96.1% and 98.2% (.2 = 0.469, p = 0.494; .2 = 1.145, p = 0.285). As the prescription dose and fraction dose in­crease, the incidence of serious adverse reactions would become significantly higher. Kwong et al.18 set the prescribed dose as 76 Gy/35F with a BED of up to 92.5 Gy. Though higher prescription dose ensured the LCR (95.7% at 3 years), 78% and 46% of patients suffered from grade 3 mucositis and skin reactions, respectively. In the study of Bakst et al.16, the total dose was 70 Gy but the fraction dose increased up to 2.34 Gy, so about 12% of patients had temporal lobe necrosis of varying degrees, es­pecially in patients with T4 whose pGTV included part of brain tissue. This situation did not appear in earlier study of the same authors in which 70 Gy/33F regimen was used.19 It could be seen that blind pursuit of high-dose or high fraction dose does not further improve LCR but might lead to more severe radiation related damage. In recent years, the hot issues about IMRT for NPC have focused on how to minimize the dose delivered to OARs and it might be realized in two main ways: 1) to improve the accuracy of radiation therapy; 2) to lower the total dose. Helical tomo­therapy (HT) is a unique IMRT modality that com­bines elements of diagnostic radiology and radia­tion therapy in a single unit. In addition to the abil­ity to deliver a highly conformal dose distribution, HT is equipped with xenon detectors designed to obtain MVCT images utilized for pre-treatment set-up verification, and some studies have con­firmed the advantage of HT compared with step­and-shoot IMRT in dose distribution and OAR protection.20-22 In this study, the Dmean of pGTVnx and pGT-Vnd decreased by 2.1 Gy and 2.2 Gy, respectively, compared to the P70 study, which was equivalent to a 2.5 Gy reduction of prescription dose. The dos­es were statistically reduced almost in all OARs ex­cept in the inner ear of which the Dmean was a bit higher and in the parotid gland with a decline of the Dmean by only 0.3 Gy. The Dmax of both eyeballs and optic nerves decreased by about 34% and 25%, respectively; the Dmean of the temporomandibu­lar joint fell by more than 5 Gy and the reduction in oral cavity was about 4.6 Gy. At the same time, the Dmean of the parotid gland remained at a high level and was far above the constraint of 28 Gy; and the incidence of grade 2 xerostomia was significant­ly higher than the P70 study (.2 = 27.225, p = 0.000). After data analysis, we noticed that acute toxici­ 225 ties were evaluated by different doctors in the two studies and acute xerostomia was underestimated in the P70 study. Leung et al.23 summarized their 5-year experience in NPC treatment with HT and the Dmean of the ipsilateral and contralateral pa­rotid gland was 22.1 Gy and 20.7 Gy, respectively, significantly lower than ours. The possible reason is delineation of the deep lobe of the parotid gland which was not spared from CTV1 in our studies. Because of the advantages of TH, the incidence of acute and late side-effects were low and acute toxicities in skin, oral mucosa, pharynx-esophagus and salivary glands were mainly graded as level 1-2 in this study. Moreover, as a proportion of lo­cally advanced cases received neoadjuvant chemo­therapy and/or concurrent chemo-radiotherapy, a higher incidence of grade 3–4 neutropenia can be accounted for. In addition, the shortening of the treatment course from 33 fractions in 6.5 weeks to 30 fractions in 6 weeks reduced treatment costs for patients as well as improving equipment turnover. Conclusions A 67.5 Gy/30F SMART regimen delivered via the HT technique appears to be associated with accept­able toxicities and favorable short-term outcomes for patients with NPC. Long-term toxicities and outcomes are under investigation. References 1. Al-Sarraf M, Le Blanc M, Giri PG, Fu KK, Cooper J, Vuong T, et al. Chemoradiotherapy versus radiotherapy in patients with advanced naso­pharyngeal cancer: phase III randomized Intergroup study 0099. J Clin Oncol 1998; 16: 1310-7. 2. Lee N, Xia P, Quivey JM, Sultanem K, Poon I, Akazawa C, et al. Intensity-modulated radiotherapy in the treatment of nasopharyngeal carcinoma: an updated of the UCSF experience. Int J Radiat Oncol Biol Phys 2002; 53: 12-22. 3. Du L, Zhang XX, Ma L, Feng LC, Li F, Zhou GX, et al. Clinical study of naso­pharyngeal carcinoma treated by helical tomotherapy in China: 5-year out­comes. Biomed Res Int 2014, Article ID: 980767. doi: 10.1155/2014/980767. 4. Fowler JF. A review: the linear quadratic formula and progress in fraction­ated radiotherapy. Br J Radiol 1989; 62: 679-94. 5. Fowler JF. 21 years of biologically effective dose. Br J Radiol 2010; 83: 554-68. 6. Cox JD, Stetz J, Pajak TF. Toxicity criteria of the Radiation Therapy Oncology Group (RTOG) and the European Organization for Research and Treatment of Cancer (EORTC). Int J Radiat Oncol Biol Phys 1995; 31: 1341-6. 7. Eisenhauer EA, Therasse P, Bogaerts J, Schwartz LH, Sargent D, Ford R, et al. New response evaluation criteria in solid tumours: revised RECIST guideline (version 1.1). Eur J Cancer 2009; 45: 228-47. 8. Lee AW, Law SC, Foo W, Poon YF, Chan DK, O SK, et al. Nasopharyngeal carci­noma: local control by megavoltage irradiation. Br J Radiol 1993; 66: 528-36. 9. Withers HR, Tayor JM, Maciejewski B. The hazard of accelerated tumor clonogen repopulation during radiotherapy. Acta Oncol 1988; 27: 131-46. 10. Withers HR. Biologic basis for altered fractionation schemes. Cancer 1985; 55(9 Suppl): 2086-95. 11. Ho KF, Fowler JF, Sykes AJ, Yap BK, Lee LW, Slevin NJ. IMRT dose fractiona­tion for head and neck cancer: variation in current approaches will make stanardisation different. Acta Oncol 2009; 48: 431-9. 12. Lee SW, Back GM, Yi BY, Choi EK, Ahn SD, Shin SS, et al. Preliminary results of a phase I/II study of simultaneous modulated accelerated radiotherapy for nondisseminated nasopharyngeal carcinoma. Int J Radiat Oncol Biol Phys 2006; 65: 152-60. 13. Lin SJ, Pan JJ, Han L, Zhang X, Liao X, Lu JJ. Nasopharyngeal carcinoma treated with reduced-volume intensity-modulated radiation therapy: report on the 3-year outcome of a prospective series. Int J Radiat Oncol Biol Phys 2009; 75: 1071-8. 14. Lee N, Harris J, Garden AS, Straube W, Glisson B, Xia P, et al. Intensity-modulated radiation therapy with or without chemotherapy for naso­pharyngeal carcinoma: Radiation Therapy Oncology Group phase II trial 0225. J Clin Oncol 2009; 27: 3684-90. 15. Xiao WW, Huang SM, Han F, Wu SX, Lu LX, Lin CG, et al. Local control, survival, and late toxicities of locally advanced nasopharyngeal carcinoma treated by simultaneous modulated accelerated radiotherapy combined with cisplatin concurrent chemotherapy: long-term results of a phase 2 study. Cancer 2011; 117: 1874-83. 16. Bakst RL, Lee N, Pfister DG, Zelefsky MJ, Hunt MA, Kraus DH, et al. Hypofractionated dose-painting intensity modulated radiation therapy with chemotherapy for nasopharygeal carcinoma: a prospective trial. Int J Radiat Oncol Biol Phys 2011; 80: 148-53. 17. Wang RS, Wu F, Lu HM, Wei B, Feng G, Li G, et al. Definitive intensity-modulated radiation therapy for nasopharyngeal carcinoma: long-term outcome of a multicenter prospective study. J Cancer Res Clin Oncol 2013; 139: 139-45. 18. Kwong DL, Sham JS, Leung LH, Cheng AC, Ng WM, Kwong PW, et al. Preliminary results of radiation dose escalation for locally advanced naso­pharyngeal carcinoma. Int J Radiat Oncol Biol Phys 2006, 64: 374-81. 19. Wolden SL, Chen WC, Pfister DG, Kraus DH, Berry SL, Zelefsky MJ. Intensity-modulated radiation therapy (IMRT) for nasopharynx cancer: update of the Memorial Sloan-Kettering experience. Int J Radiat Oncol Biol Phys 2006; 64: 57-62. 20. Bauman G, Yartsev S, Rodrigues G, Lewis C, Venkatesan VM, Yu E, et al. A prospective evaluation of helical tomotherapy. Int J Radiat Oncol Biol Phys 2007; 68: 632-41. 21. Lee N, Xia P, Quivey JM, Sultanem K, Poon I, Akazawa C, et al. Intensity-modulated radiotherapy in the treatment of nasopharyngeal carcinoma: an update of the UCSF experience. Int J Radiat Oncol Biol Phys 2002; 53: 12-22. 22. Fiorino C, Dell’Oca I, Pierelli A, Broggi S, Cattaneo GM, Chiara A, et al. Simultaneous integrated boost (SIB) for nasopharynx cancer with helical tomotherapy. A planning study. Strahlenther Oncol 2007; 183: 497-505. 23. Leung SW, Lee TF. Treatment of nasopharyngeal carcinoma by tomotherapy: five-year experience. Radiat Oncol 2013; 8: 107-12. research article Bevacizumab plus chemotherapy in elderly patients with previously untreated metastatic colorectal cancer: single center experience Janja Ocvirk1,2, Maja Ebert Moltara1,Tanja Mesti1, Marko Boc1, Martina Rebersek1, Neva Volk1, Jernej Benedik1, Zvezdana Hlebanja1 1 Department of Medical Oncology, Institute of Oncology Ljubljana, Ljubljana, Slovenia 2 Faculty of Medicine, University of Ljubljana, Ljubljana, Slovenia Radiol Oncol 2016; 50(2): 226-231. Received 3 September 2014 Accepted 7 October 2014 Correspondence to: Assoc. Prof. Janja Ocvirk, M.D., Ph.D., Institute of Oncology Ljubljana, Zaloška 2, Ljubljana. Phone: +386 1 5879 220; Fax: +386 1 5879 305; E-mail: jocvirk@onko-i.si Disclosure: No potential conflicts of interest were disclosed. Background. Metastatic colorectal cancer (mCRC) is mainly a disease of elderly, however, geriatric population is underrepresented in clinical trials. Patient registries represent a tool to assess and follow treatment outcomes in this pa­tient population. The aim of the study was with the help of the patients’ register to determine the safety and efficacy of bevacizumab plus chemotherapy in elderly patients who had previously untreated metastatic colorectal cancer. Patients and methods. The registry of patients with mCRC was designed to prospectively evaluate the safety and efficacy of bevacizumab-containing chemotherapy as well as selection of patients in routine clinical practice. Patient baseline clinical characteristics, pre-specified bevacizumab-related adverse events, and efficacy data were collected, evaluated and compared according to the age categories. Results. Between January 2008 and December 2010, 210 patients with mCRC (median age 63, male 61.4%) started bevacizumab-containing therapy in the 1st line setting. Majority of the 210 patients received irinotecan-based chemo­therapy (68%) as 1st line treatment and 105 patients (50%) received bevacizumab maintenance therapy. Elderly (. 70 years) patients presented 22.9% of all patients and they had worse performance status (PS 1/2, 62.4%) than patients in < 70 years group (PS 1/2, 35.8%). Difference in disease control rate was mainly due to inability to assess response in elderly group (64.6% in elderly and 77.8% in < 70 years group, p = 0.066). The median progression free survival was 10.2 (95% CI, 6.7–16.2) and 11.3 (95% CI, 10.2–12.6) months in elderly and < 70 years group, respectively (p = 0.58). The me­dian overall survival was 18.5 (95% CI, 12.4–28.9) and 27.4 (95% CI, 22.7–31.9) months for elderly and < 70 years group, respectively (p = 0.03). Three-year survival rate was 26% and 37.6% in elderly vs. < 70 years group (p = 0.03). Overall rates of bevacizumab-related adverse events were similar in both groups: proteinuria 21/22 %, hypertension 25/19 %, haemorrhage 2/4 % and thromboembolic events 10/6 %, for elderly and < 70 years group, respectively. Conclusions. In routine clinical practice, the combination of bevacizumab and chemotherapy is effective and well-tolerated regimen in elderly patients with metastatic colorectal cancer. Key words: metastatic colorectal cancer; bevacizumab; chemotherapy; elderly Introduction As with many cancers, metastatic colorectal cancer (mCRC) is mainly a disease of elderly population. However, geriatric population is underrepresent­ed in clinical trials. The median age at diagnosis for patients with CRC is 72 years, while the me­dian age of patients in clinical trials is 63 years.1 In Slovenia, 44% of colorectal cancer cases were diag­nosed in people aged 70 years and over.2 Age to­gether with performance status and comorbidities is one of the most important factors when deciding 227 on treatment regimen.3 Studies show that close to half of the elderly patients with stage III colon can­cer do not receive chemotherapy, although most of the studies and meta-analysis have reported simi­lar response rate (ORR), overall survival (OS), time to progression (TTP) and tolerability for elderly and younger patients in adjuvant and metastatic setting.4-6 Addition of bevacizumab, a humanized mon­oclonal antibody against vascular endothelial growth factor, to the chemotherapy backbone regi­mens improves progression-free survival (PFS) and overall survival in first-line and second-line treatment and when continued beyond first pro­gression in mCRC.7 Data from large observational studies, subgroup analysis and pooled analysis of randomized trials have suggested that the survival benefits associated with the use of bevacizumab in the first-line treatment are similar in elderly and general population.8-13 With the introduction of bevacizumab as standard of care for mCRC pa­tients in Slovenia14, our centre has created patient registry to prospectively assess patient selection as well as efficacy and safety of bevacizumab con­taining chemotherapy in routine clinical practice. This registry enabled data capturing of the mCRC management in geriatric population that is usu­ally excluded in clinical research and comparison of clinical outcomes to their younger counterparts. The aim of the study was with the help of the patients’ register to determine the safety and effi­cacy of bevacizumab plus chemotherapy in elderly patients who had previously untreated metastatic colorectal cancer. Patients and methods Patient clinical baseline characteristics, pre-speci­fied bevacizumab-related adverse events, and effi­cacy data were prospectively collected within local patient registry from 210 mCRC patients who start­ed bevacizumab-containing chemotherapy in the 1st line setting. Patient clinical characteristics (pri­mary tumour treatments, an Eastern Cooperative Oncology Group [ECOG] performance status [PS], metastatic burden), rate of bevacizumab-related toxicities, metastasectomy rate, ORR, PFS and OS were evaluated. The study was done in accordance with the prin­ciples of Good Clinical Practice and the Declaration of Helsinki and was approved by national ethics committee. All patients provided written informed consent for data collection. Statistical analysis Statistical analyses were performed on the intent-to-treat (ITT) population e.g. patients who received at least one dose of bevacizumab. Patient character­istics and toxicity data were summarized descrip­tively by the age group. Proportions of categori­cal variables were compared using the chi-square test. Survival analyses were performed using the Kaplan-Meier method, which provided medians and 95% confidence intervals (CIs). The differences in survival were evaluated using the log rank test; the follow-up time for this comparison was limited to 3 years, which is the minimum period available for all the patients. Results Patient characteristics The data from 210 patients (median age 63, males 61.4%) treated with bevacizumab-containing chemotherapy (B-CTX) in the 1st line setting in rou­tine clinical practice were included in the evalua­tion. The patients with mCRC started B-CTX treat­ment between January 2008 and December 2010 and were followed for outcomes at our centre until December 2013. The ECOG PS at baseline was 0 in 58%, 1 in 38% and 2 in 4% of all patients. Subgroup Elderly patients (. 70 years, n = 48) presented 22.9% of all patients and they had worse performance sta­tus (PS1/2 62.4%) than patients in < 70 years group (PS1/2 35.8%). Patient characteristics are described in Table 1. Metastatic disease was the first diagno­sis in 63% of patients < 70 years old, while in the elderly patients only 45.8% had mCRC as the first diagnosis of CRC. Treatment Bevacizumab 5 mg/kg every two weeks or 7.5 mg/ kg every three weeks was administered in combi­nation with chemotherapy (CTX) to the patients with mCRC. Majority of 210 patients received irinotecan-based chemotherapy (68%) as 1st line treatment and 105 patients (50%) received beva­cizumab maintenance therapy. The patients in < 70 years group received mainly irinotecan-based chemotherapy (66%) - capecitabine plus irinote­can (XELIRI) 58.6%, capecitabine plus oxaliplatin (XELOX) 27.8%, leucovorin, fluorouracil plus iri­notecan (FOLFIRI) 6.8%, leucovorin, fluorouracil plus oxaliplatin (FOLFOX) 4.9%, monotherapy capecitabine or irinotecan 1.8%. Median duration TABLE 1. Patient characteristics at baseline Gender, n (%) Men 96 (60) 33 (70) Women 64 (40) 14 (30) Age FIGURE 1. Kaplan-Meier survival curves for Progression Free Survival and Overall Median, years 59 72 Survival in patients aged < 70 years and . 70 years. Range, years 24–69 70–81 ECOG performance status, n (%) 0 104 (64) 18 (38) TABLE 2. Efficacy outcomes 1 52 (32) 27 (56) 2 3 6 (4) 0 3 (6) 0 Best response, n (%) Site of metastatic disease, n (%) Complete 9 (6) 4 (8) Liver 112 (69) 35 (73) Partial 60 (37) 13 (27) Lung 39 (24) 12 (25) Stable disease 57 (35) 14 (29) Lymph nodes 42 (26) 12 (25) Progressive disease 21 (13) 6 (13) Bones 6 (4) 3 (6) Not evaluable 7 (4) 6 (13) Other 64 (40) 13 (27) Overall response rate, % (95% CI) Disease-control rate, % (95% CI) Progression free survival, months Median 69 (43) 126 (78) 11.3 17 (35) 31 (65) 10.2 Primary tumour location, n (%) Colon only Rectum only 106 (65) 56 (35) 31 (65) 16 (33) (95% CI) (10.2–12.6) (6.7–16.2) Colon and rectum 0 1 (2) Overall survival, months Adjuvant chemotherapy, n (%) 50 (31) 18 (38) Median (95% CI) 27.4 (22.7–31.9) 18.5 (12.4–28.9) Previous radiotherapy, n (%) 30 (19) 9 (19) Metastasectomy, n (%) 32 (21.2) 6 (15) Surgical resection, n (%) 132 (82) 42 (88) CI = confidence interval of B-CTX was 24 weeks (range 3 to 36) and the me­dian number of treatment cycles was 8 (range 1 to 16). In this group of patients, maintenance beva­cizumab was administered to 83 patients (51%), with median number of cycles 6 (range 1 to 70). The backbone chemotherapy in patients aged . 70 years was also mostly irinotecan (75%) - XELIRI 60.4%, XELOX 14.6%, FOLFIRI 10.4%, FOLFOX 6.2%, monotherapy capecitabine or irinotecan 8.4%. Median duration of B-CTX in elderly was 17 weeks (range 3 to 36) and the median number of treatment cycles was 6 (range 1 to 12). Twenty one patients (44%) received maintenance bevacizumab with median number of cycles 5 (range 1 to 51). Treatment interruption was reported in 20.4% of patients in < 70 years group and 14.6% of patients . 70 years group. Two main reasons for bevacizumab discontinuation in < 70 years group were disease progression (49% of all patients that discontin­ ued) and adverse events (25%). In . 70 years group bevacizumab was discontinued due to disease pro­gression (35%) and adverse events (20%), but 15% of patients were lost to follow-up. Efficacy Efficacy data are summarized in Table 2. Difference in disease control rate (DCR) was mainly due to in­ability to assess response in elderly group (64.6% in elderly and 77.8% in < 70 years group). ORR and DCR did not differ significantly be­ tween the two groups (p = 0.375 and p = 0.066, respectively). The median PFS was 10.2 (95% CI, 6.7.16.2) and 11.3 (95% CI, 10.2.12.6) months in elderly and < 70 years group, respectively (p = 0.58) (Figure 1). The median OS was 18.5 (95% CI, 229 12.4–28.9) and 27.4 (95% CI, 22.7.31.9) months for elderly and < 70 years group, respectively (p = 0.03) (Figure 1). Metastasectomy was performed in 6 (15%) of el­derly patients and 32 (21.2%) patients in < 70 years group. Three-year survival rate was 26% (95% CI, 15.3.44.2) and 37.6% (95% CI, 30.7.46.1) in elderly vs. < 70 years group (p = 0.03). In elderly patients, 15 patients received second-line therapy, all of them receiving bevacizumab in combination with subsequent chemotherapy. In patients aged < 70 years, 101 patients received second-line therapy, out of which 76% contained bevacizumab. Toxicity Adverse events related to bevacizumab were re­ported in 123 (75.9%) and 38 (79.2%) patients in < 70 years and . 70 years group, respectively. Adverse events of special interest to bevacizumab are summarized in Table 3 (epistaxis excluded). A case of vesico-rectal fistula was reported in the patient aged < 70 years (rectal cancer with previ­ous radiotherapy). One case of acute myocardial infarction was reported in each group. One patient on capecitabine monotherapy from elderly group presented with adverse event with an outcome death (heart failure). The incidence of adverse event that led to bev­acizumab discontinuation was 19% in both age groups. The incidence of adverse event that led to bevacizumab dose interruption was 10.5% and 10% in patients aged < 70 and . 70 years, respectively. Discussion Randomized studies, subgroup and pooled analy­sis, along with large observational studies suggest that bevacizumab containing first-line chemother­apy is efficacious and safe in elderly patients with mCRC. Randomized phase II trial of bevacizumab or placebo added to 5-FU in elderly patients not suitable for irinotecan treatment reported sig­nificantly longer PFS in patients who received bevacizumab versus placebo (9.2 months versus 5.5 months, respectively, hazard ratio, 0.5; p = 0.0002).15 Furthermore, results from phase III trial AVEX showed that in patients over age of 70 years and non-fit for oxaliplatin or irinotecan-based chemotherapy, PFS was significantly longer in the group of patients who received bevacizumab plus capecitabine versus the capecitabine alone group TABLE 3. Targeted adverse events < 70 years (n = 162) Hypertension 11 (6.8) 15 (9.3) 5 (3.1) 0 (0) 30 (18.5) Thromboembolism 1 (0.6) 4 (2.5) 4 (2.5) 0 (0) 9 (5.6) Proteinuria 23 (14.2) 11 (6.8) 2 (1.2) 0 (0) 36 (22.2) Hemorrhage 4 (2.5) 1 (0.6) 0 (0) 1 (0.6) 6 (3.7) Infection 4 (2.5) 1 (0.6) 4 (2.5) 0 (0) 8 (4.9) > 70 years (n = 48) Hypertension 3 (6.2) 6 (12.5) 2 (4.2) 0 (0) 12 (25) Thromboembolism 0 (0) 1 (2.1) 2 (4.2) 2 (4.2) 5 (10.4) Proteinuria 7 (14.6) 3 (6.2) 0 (0) 0 (0) 10 (20.8) Hemorrhage 0 (0) 0 (0) 1 (2.1) 0 (0) 1 (2.1) Infection 0 (0) 1 (2.1) 0 (0) 0 (0) 1 (2.1) (9.1 versus 5.1 months, p < 0.0001).16 The subanaly­sis of the BICC-C study (bevacizumab + FOLFIRI or mIFL) reported no difference in efficacy and safety for mCRC patients > 70 years compared with patients . 70 years (PFS 7.6 months com­pared to 10.7 months, p = 0.14, with FOLFIRI/Bev ORR 57% > 70 years and 58% . 70 years).11 Pooled analysis of four randomized trials (three first-line and one second-line treatment, n = 3,007)), where patients were treated with fluoropyrimidine­based chemotherapy with or without bevacizum­ab, showed that addition of bevacizumab to CTX significantly prolonged PFS in older and younger patients with similar magnitude of PFS benefit (hazard ratios were 0.59, 0.58 and 0.54 in patients aged < 65 years, . 65 years and . 70 years, respec­tively). In addition, OS in both older and younger patients was statistically significantly prolonged by addition of bevacizumab to CTX (median OS was 19.9 months in patients aged < 65 years, 17.9 months in patients . 65 years and 17.4 months in those aged . 70 years).13 Recent results from phase II study BECOX suggest that bevacizumab plus XELOX is effective and well tolerated in elderly mCRC patients with time to progression of 11.1 months, median OS of 20.4 months and ORR of 46%.17 Bevacizumab-containing CTX outcomes from routine clinical practice were monitored and/or reported in mCRC patients registries such as pro­spective US BRiTE registry (n = 1,953)9 or retro­spective Czech (n = 3,187) and French (n = 1,322) registries.10,18 These large first-line setting registries confirmed similarity of clinical benefit between younger and older patients, previously reported in randomized clinical trials and pooled analysis. Safety profile for all these studies is generally similar in older and younger patients, except for thromboembolic events, which were more com­mon in the older group. Within local registry of patients with metastatic colorectal cancer, we have assessed efficacy and safety of bevacizumab in combination with vari­ous chemotherapy regimens and compared data between two age groups - patients aged below and over 70 years. While other registries as backbone chemothera­py reported use of primarily oxaliplatine-based first line chemotherapy (FOLFOX followed by XELOX or FOLFIRI) with trend of increased monotherapy use in elderly population, in our centre backbone chemotherapy was in majority of patients (68%) iri­notecan-based. Specifically, bevacizumab was ad­ministered mainly with XELIRI (58.6% in < 70 years group and 60.4% in . 70 years group) followed by XELOX (27.8% in < 70 years group and 14.6% in . 70 years group) with low rate of monotherapy use (1.8% and 8.4% for < 70 years and . 70 years, respec­tively). Although median duration of B-CTX in el­derly was 17 weeks and in patients aged < 70 years was 24 weeks, maintenance with bevacizumab was well tolerated in both groups with median number of cycles 6 and 5 for < 70 years (51% of patients) and . 70 years group (44% of patients), respectively. ORR and DCR did not differ significantly between the two groups (p = 0.375 and p = 0.066, respective­ly) which is in concordance with other studies. The median PFS of 10.2 and 11.3 months in elderly and < 70 years group, respectively (p = 0.58) is also com­parable to findings in other studies. In BRiTE reg­istry, even after adjusting for significant baseline covariates such as ECOG PS or site and surgical resection of primary tumour, decreasing median OS in older age cohorts was observed.9 Similarly, in our study median OS was 18.5 and 27.4 months for elderly and < 70 years group, respectively (p = 0.03). This can be partially explained by worse PS in elderly (PS1/2 62.4%) than patients in < 70 years group (PS1/2 35.8%). Selection bias and influence of comorbidities and presence of synchronous me­tastasis that were not captured cannot be excluded. In the registry, only bevacizumab-associated ad­verse event information was collected. A disadvan­tage of our registry was lack of data for chemother­apy induced adverse events. This was not in scope of the registry, as in an earlier retrospective study from our group, where we compared XELIRI/ bevacizumab to FOLFIRI/bevacizumab (age range 31.77 years), we have reported similar efficacy and safety data between two chemotherapy regimens, but with more grade 3/4 neutropenia in FOLFIRI/ bevacizumab combination, and more grade 3/4 diarrhoea in XELIRI/bevacizumab, findings con­firmed also by other studies.19,20 The rates of most bevacizumab-targeted adverse events in the older patient group were similar to rates in the patients aged < 70 years. They were also comparable to previously reported overall rates of adverse events.9,13,15 The most common bevacizum­ab-associated adverse events were hypertension and proteinuria, with hypertension being slight­ly more observed in elderly (25% vs. 18.5%). No grade 4 or 5 hypertensive events were recorded. Thromboembolic events were reported in 10.4% of elderly patients compared to 5.6% in patients aged < 70 years. The increase of arterial thromboembo­lism in elderly treated with bevacizumab, but no change in venous thromboembolic events, was pre­viously reported in pooled analysis of four rand­omized trials as well as in large patient registry.9,13 Conclusions Our single centre experience present new set of da­ta confirming PFS and OS benefit of bevacizumab containing, predominantly irinotecan-based first-line chemotherapy in mCRC patients in routine clinical practice. This benefit was observed in both elderly and patients aged < 70 years with manage­able safety profile. Proper selection of patients with mCRC can result in a safe and beneficial B-CTX treatment results in older patients with similar outcomes to their younger counterparts, therefore, chronological age does not present exclusion to treatment with bevacizumab. Acknowledgements The independent analysis of data was performed by Institute for Biostatistics and Medical Informatics at University of Ljubljana, Slovenia. This research was partially supported by Roche. References 1. Schmoll HJ, Van Cutsem E, Stein A, Valentini V, Glimelius B, Haustermans K, et al. ESMO consensus guidelines for management of patients with colon and rectal cancer. A personalized approach to clinical decision making. Ann Oncol 2012; 23: 2479-516. 231 2. Cancer in Slovenia 2010. Ljubljana: Institute of Oncology Ljubljana, Epidemiology and Cancer Registry, Cancer Registry of Republic of Slovenia; 2013. 3. Zwitter M, Kovac V, Rajer M, Vrankar M, Smrdel U. Two schedules of chemo­therapy for patients with non-small cell lung cancer in poor performance status: a phase II randomized trial. Anticancer Drugs 2010; 21: 662-8. 4. Sundararajan V, Mitra N, Jacobson JS, Grann VR, Heitjan DF, Neugut AI. Survival associated with 5-fluorouracil-based adjuvant chemotherapy among elderly patients with node positive colon cancer. Ann Intern Med 2002; 136: 349-57. 5. Folprecht G, Cunningham D, Ross P, Glimelius B, Di Costanzo F, Wils J, et al. Efficacy of 5-fluorouracil-based chemotherapy in elderly patients with metastatic colorectal cancer: A pooled analysis of clinical trials. Ann Oncol 2004; 15: 1330-8. 6. Köhne CH, Folprecht G, Goldberg RM, Mitry E, Rougier P. Chemotherapy in elderly patients with colorectal cancer. Oncologist 2008; 13: 390-402. 7. Ocvirk J. Advances in the treatment of metastatic colorectal carcinoma. Radiol Oncol 2009; 43: 1-8. 8. Van Cutsem E, Rivera F, Berry S, Kretzschmar A, Michael M, DiBartolomeo M, et al. Safety and efficacy of first-line bevacizumab with FOLFOX, XELOX, FOLFIRI and fluoropyrimidines in metastatic colorectal cancer: the BEAT study. Ann Oncol 2009; 29: 1842-7. 9. Kozloff MF, Berlin J, Flynn PJ, Kabbinavar F, Ashby M, Dong W, et al. Clinical outcomes in elderly patients with metastatic colorectal cancer receiving bevacizumab and chemotherapy: results from the BRiTE observational cohort study. Oncology 2010; 78: 329-39. 10. Slavicek L, Pavlik T, Tomasek J, Bortlicek Z, Buchler T, Melichar B, et al. Efficacy and safety of bevacizumab in elderly patients with metastatic colorectal cancer: results from the Czech population-based registry. BMC Gastroenterology 2014; 14: 53. 11. Jackson NA, Barrueco J, Soufi-Mahjoubi R, Marshall J, Mitchell E, Zhang X, et al. Comparing safety and efficacy of first-line irinotecan/fluoropirimidine combinations in elderly versus nonelderly patients with metastatic colorec­tal cancer. Cancer 2009; 115: 2617-29. 12. Price TJ, Zannino D, Wilson K, Simes J, Cassidy J, Van Hazel GA, et al. Bevacizumab is equally effective and no more toxic in elderly patients with advanced colorectal cancer: a subgroup analysis from the AGITG MAX trial: an international randomised controlled trial of capecitabine, bevacizumab and mytomycin C. Ann Oncol 2012; 23: 1531-6. 13. Cassidy J, Saltz LB, Giantonio BJ, Kabbinavar FF, Hurwitz HI, Rohr UP. Effect of bevacizumab in older patients with metastatic colorectal cancer: pooled analysis of four randomized studies. J Cancer Res Clin Oncol 2010; 136: 737-43. 14. Mesti T, Boshkoska BM, Kos M, Tekavčič M, Ocvirk J. The cost of systemic therapy for metastatic colorectal carcinoma in Slovenia: Discrepancy analy­sis between cost and reimbursement. Radiol Oncol 2015; 49: 200-8. 15. Kabbinavar FF, Schulz J, McCleod, Patel T, Hamm JT, Hecht JR, et al. Addition of bevacizumab to bolus fluorouracil and leucovorin in first-line metastatic colorectal cancer: results of randomized phase II trial. J Clin Oncol 2005; 23: 3697-705. 16. Cunningham D, Lang I, Marcuello E, Lorusso V, Ocvirk J, Shin DB, et al. Bevacizumab plus capecitabine versus capecitabine alone in elderly patients with previously untreated metastatic colorectal cancer (AVEX): an open label, randomized phase 3 trial. Lancet Oncol 2013; 14: 1077-85. 17. Feliu J, Salud A, Safont MJ, Garcia-Girón C, Aparicio J, Vera R, et al. First-line bevacizumab and capecitabine-oxaliplatine in elderly patients with mCRC: GEMCAD phase II BECOX study. Br J Cancer 2014; 111: 241-8. 18. Doat S, Thiébaut A, Samson S, Ricordeau P, Guillemont D, Mitry E. Elderly patients with colorectal cancer: treatment modalities and survival in France. National data from the ThInDiT cohort study. Eur J Cancer 2014; 50: 1276-83. 19. Ocvirk J, Rebersek M, Boc M. Bevacizumab in first-line therapy of meta­static colorectal cancer: a retrospective comparison of FOLFIRI and XELIRI. Anticancer Res 2011; 31: 1777-82. 20. Ducreux M, Adenis A, Pignon J-P, François E, Chauffert B, Ichanté JL, et al. Efficacy and safety of bevacizumab-based combination regimens in patients with previously untreated metastatic colorectal cancer: Final results from a randomised phase ii study of bevacizumab plus5-fluorouracil, leucov­orin plus irinotecan versus bevacizumab plus capecitabine plus irinotecan (FNCLCC ACCORD 13/0503 study). Eur J Cancer 2013; 49: 1236-45. research article The dosimetric significance of using 10 MV photons for volumetric modulated arc therapy for post-prostatectomy irradiation of the prostate bed Henry Kleiner1,2, Matthew B. Podgorsak1,2 1 Department of Physiology and Biophysics, SUNY University at Buffalo, Buffalo, NY, USA 2 Department of Radiation Medicine, Roswell Park Cancer Institute, Buffalo, NY, USA Radiol Oncol 2016; 50(2): 232-237. Received 21 September 2015 Accepted 8 January 2016 Correspondence to: Henry Kleiner, MS, Department of Physiology and Biophysics, SUNY University at Buffalo, Buffalo, NY, USA and Department of Radiation Medicine, Roswell Park Cancer Institute, Buffalo, NY, USA. E-mail: henry.kleiner@gmail.com Disclosure: No potential conflicts of interest were disclosed. Background. The purpose of the study was to analyse the dosimetric differences when using 10 MV instead of 6 MV for VMAT treatment plans for post-prostatectomy irradiation of the prostate bed. Methods and materials. Ten post-prostatectomy prostate bed irradiation cases previously treated using 6 MV with volumetric modulated arc therapy (VMAT) were re-planned using 10 MV with VMAT. Prescription dose was 66.6 Gy with 1.8 Gy per fraction for 37 daily fractions. The same structure set, number of arcs, field sizes, and minimum dose to the Planning Target Volume (PTV) were used for both 6 MV and 10 MV plans. Results were collected for dose to Organs at Risk (OAR) constraints, dose to the target structures, number of monitor units for each arc, Body V5, Conformity Index, and Integral Dose. The mean values were used to compare the 6 MV and 10 MV results. To determine the statistical significance of the results, a paired Student t test and power analysis was performed. Results. Statistically significant lower mean values were observed for the OAR dose constraints for the rectum, bladder-Clinical Target Volume (bladder-CTV), left femoral head, and right femoral head. Also, statistically significant lower mean values were observed for the Body V5, Conformity Index, and Integral Dose. Conclusions. Several dosimetric benefits were observed when using 10 MV instead of 6 MV for VMAT based treat­ment plans. Benefits include sparing more dose from the OAR while still maintaining the same dose coverage to the PTV. Other benefits include lower Body V5, Conformity Index, and Integral Dose. Key words: volumetric modulated arc therapy (VMAT); prostate bed; 10 MV; 6 MV; radiation therapy Introduction In radiation therapy, high energy photons are used to deliver x-rays to a tumor target. It is known that as the energy of the photons is increased, they will penetrate deeper into tissue resulting in more ra­diation dose being delivered to the tumor target. This has been observed when treating prostate cancer with three dimensional conformal radiation therapy (3DCRT).1 However, as the photon energy is increased, two issues arise: an increase in the penumbra and the production of secondary neutrons from the head of the linac when using photon energies greater than or equal to 10 MV.2-4 As the technology of radia­tion therapy has changed, 3DCRT has given way to Intensity Modulated Radiation Therapy (IMRT), with 6 MV being the most commonly used beam energy in IMRT treatment planning. IMRT allows more dose to be delivered to the tumor target with less dose being deposited to adjacent organs at risk (OAR), as seen in two studies of prostate cancer.5,6 For treatment plans using IMRT, numerous studies have been conducted about the impact of differ­ 233 ent photons energies in treating prostate cancer.7-14 Some of these studies show no clear benefit to us­ing higher energy photons. Volumetric Modulated Arc Therapy (VMAT) has now begun to replace IMRT for treating pros­tate cancer, and numerous studies show that using VMAT instead of IMRT for prostate cancer results in dosimetric benefits, such as reduced treatment time and more dose sparing to OAR.15-20 Therefore, it is relevant to investigate if using higher energy pho­tons has greater potency than using the traditional 6 MV for VMAT. To deal with the issue of neutron contamination, 10 MV photons were used for this work since the issue of neutron production for high­er photon energies is negligible at that energy.21 When deciding which cancer type would be ap­propriate for conducting this study, we chose pros­tate cancer patients who were undergoing post­prostatectomy irradiation of the prostate bed. The reason for this selection is two-fold. The first reason is that we wanted a location with a deep seated tar­get volume. This would ensure that using photon beam energies higher than 6 MV would result in x-rays that would penetrate into the target; photon beam energies greater than 6 MV would not be use­ful for a shallower target. The second reason is due to there being no requirement for additional boost plans. This allows the same plan to be used during the entire course of patient treatment, requires less treatment planning time per patient, and reduces the complexity of the plan. Materials and methods Ten cases of prostate cancer patients who had undergone a prostatectomy and received irradia­tion of the prostate bed using 6 MV photons with VMAT at Roswell Park Cancer Institute were se­lected for a retrospective study. These cases were re-planned using 10 MV photons with VMAT, and were compared to the clinically used 6 MV plans. The prescription dose was kept the same at 66.6 Gy for all ten cases for both beam energies, with 1.8 Gy per fraction in 37 daily fractions. Treatment plans were created with the Varian Eclipse ver­sion 11 treatment planning system (Varian Medical Systems, Inc., Palo Alto, CA, USA). The Varian im­plementation of VMAT is known as RapidArc and used Anisotropic Analytical Algorithm version 10 and Progressive Resolution Optimizer version 10. Two complete arcs were used for all ten cases for both beam energies. For each patient, the field sizes for the 10 MV plan were kept the same as the cor­responding 6 MV plan. Structure sets containing regions of interest were generated using CT based contouring, and the same structure set was used for both sets of treatment plans for dose measure­ment purposes. For each patient, the same mini­mum dose to the planning target volume (PTV) structure that existed for each 6 MV plan was used for the corresponding 10 MV plan. This was done as a baseline to compare the 6 MV and 10 MV plans for each patient. It should be noted that this study was performed using only a treatment planning system. There was no actual treatment plan veri­fication of dose delivery by the linear accelerator. Plan evaluation was based on the OAR dose con­straint categories provided in Radiation Therapy Oncology Group (RTOG) protocol 0534.22 Based on this protocol, values were collected for the fol­lowing OAR dose constraint categories: Bladder-Clinical Target Volume (Bladder-CTV) D50, Bladder-CTV D70, Rectum D35, Rectum D55, Right Femoral Head D10, and Left Femoral Head D10. Bladder-CTV was created by cropping out the part of the blad­der that overlaps with the CTV structure. For each plan, the cumulative dose volume histogram was used to collect these values. We also collected the minimum dose, maximum dose, and mean dose for the CTV and PTV, and the volume percentages of the CTV and the PTV that receives 95% of the pre­scription dose of 66.6 Gy. We also collected values for the Body V5, the number of monitor units for the first and second arcs, the Conformity Index, and the Integral Dose. The Body V5 provided a measure­ment of low dose exposure to the Body as contoured in the treatment planning system. The International Committee for Radiation Units (ICRU) report 62 defined the Conformity Index as the ratio between the treated volume receiving a selected dose and the PTV volume receiving a selected dose.23 Based on ICRU report 62, we defined the Conformity Index in our study as the ratio between the Body volume receiving 66.6 Gy and the PTV volume receiving 66.6 Gy. We defined the Integral Dose as the vol­ume of the Body-PTV structure multiplied by the mean dose to the Body-PTV. The Body-PTV struc­ture was created by cropping out the section of the Body structure that overlapped with the PTV. For each category of interest, the results collected for both energies were used to generate a mean along with a standard deviation of the mean for 6 MV and 10 MV. To determine the statistical significance of our results, a paired Student t test and power analy­sis was conducted using the R statistical software package version 3.2.3.24 The OAR dose constraint limits were adapted from RTOG protocol 0534, and are presented in Table 1. We did not want the dose to the OAR to exceed these limits. Additional optimization structures were used for the 10 MV treatment plans in order to spare dose to the OAR and increase dose to the PTV. These structures were labeled PTVx, Bladder-PTVx, Rectum-PTVx, Penile Bulb-PTVx, Rectum 7 mm, and Rectum Mid. The PTVx is created from the PTV with a margin expansion of 1 mm in all directions. The Bladder-PTVx structure is created by cropping out the portion of the bladder that overlaps with the PTVx with a 3 mm separation between the new structure and the PTVx. The Rectum-PTVx structure is created by cropping out the portion of the rectum that overlaps with the PTVx with a 3 mm separa­tion between the new structure and the PTVx. The Penile Bulb-PTVx structure is created by cropping out the portion of the penile bulb that overlaps with the PTVx with a 3 mm separation between the new structure and the PTVx. Not every plan had this structure due to the possibility that the penile bulb completely overlaps with the PTVx. The Rectum 7 mm structure was created through several steps. First, the Rectum-PTVx structure is created with no additional separation. Then, this structure is ex­panded by 5 mm on all sides. This new structure is cropped out from the PTVx with an additional margin of 7 mm. Any instances of the Rectum 7 mm structure on slices where the PTVx structure did not exist were erased. The Rectum Mid structure was created through several steps. First, the Rectum-PTVx structure is created with no additional sepa­ration. This structure is expanded the margin by 5 mm on all sides. Then, using a Boolean operation, this structure is cropped from the Rectum 7 mm structure. This new structure is then cropped from the PTVx structure with an additional separation of 3 mm. Any instances of the Rectum Mid structure on CT slices where the PTVx structure did not exist were erased. These two structures Rectum Mid and Rectum 7 mm were created to move the 50% isodose line away from the posterior portion of the rectum. This is due to a study that showed an increased com­plication risk if the 50% isodose line falls outside the rectum.25 Additionally, we want the 90% isodose line to fall at half the width posteriorly in the rectum and the 50% isodose line should fall at less than half the full width posteriorly in the rectum. Results For each category in Table 2, the mean, standard deviation of the mean (SDOM), the percent in- TABLE 1. Dose constraint limits adapted from RTOG protocol 0534 Bladder-CTV D50 65 Gy Bladder-CTV D70 40 Gy Rectum D35 65 Gy Rectum D55 40 Gy Right Femoral Head D10 50 Gy Left Femoral Head D10 50 Gy CTV = Clinical Target Volume crease, the p-value, and the power of the statistical test are presented below. The percent increase is the increase (or decrease) when transitioning from the 6 MV mean to the corresponding 10 MV mean. A negative sign in the percent increase column in­dicates a percent decrease going from 6 MV to 10 MV. A p-value less than or equal to 0.05 is consid­ered statistically significant. Looking at Table 2, we see that all the values for the OAR dose constraint categories show a lower dose when using 10 MV in place of 6 MV. We also see more than 10% reduction in the mean dose for the categories Bladder-CTV D70, Right Femoral Head D10, and Left Femoral Head D10. Note that the 6 MV and 10 MV results for all OAR dose con­straint categories were much lower than the dose limits set by the RTOG 0534 protocol displayed in Table 1. For the two categories CTV Percent Volume Covered by the 95% Isodose Line and PTV Percent Volume Covered by the 95% Isodose Line, we ob­served that 100% of the respective target structure received 95% of the prescription dose of 66.6 Gy for all ten patients for both 6 MV and 10 MV. Therefore, there is no standard deviation of the mean and no p-value to be found for these two categories. Looking at the p-values less than or equal to 0.05 in Table 2, we see that the 10 MV results are sta­tistically significant for the following categories: Bladder-CTV D50, Bladder-CTV D70, Rectum D35, Rectum D55, Right Femoral Head D10, Left Femoral Head D10, CTV Mean Dose, Body V5, Conformity Index, and Integral Dose. The following categories had a p-value greater than 0.05, and therefore are not statistically significant: CTV Min Dose, CTV Max Dose, PTV Min Dose, PTV Max Dose, PTV Mean Dose, Global Max Dose, Arc 1 Monitor Units, and Arc 2 Monitor Units. It should be noted that for the number of MU for the first arc, eight of the ten 235 TABLE 2. Mean, standard deviation of the mean, percent increase, p-value, and power for both 6 MV and 10 MV are displayed Bladder-CTV D50 32.5 ± 4.3 Gy 29.7 ± 3.9 Gy -8.62% 0.013 0.79 Bladder-CTV D70 18.5 ± 3.7 Gy 16.2 ± 3.2 Gy -12.4% 0.011 0.81 Rectum D35 49.5 ± 3.3 Gy 46.8 ± 3.9 Gy -5.45% 6.6 × 10-3 0.88 Rectum D55 28.5 ± 2.7 Gy 26.7 ± 2.7 Gy -6.32% 0.023 0.68 Right Femoral Head D10 34.12 ± 0.86 Gy 29.80 ± 0.99 Gy -12.66% 1.2 × 10-4 1.0 Left Femoral Head D10 32.74 ± 0.94 Gy 29.4 ± 1.1 Gy -10.20% 8.3 × 10-5 1.0 CTV Min Dose 65.53 ± 0.38 Gy 65.29 ± 0.21 Gy -0.3662% 0.41 0.12 CTV Max Dose 71.01 ± 0.37 Gy 70.53 ± 0.31 Gy -0.6760% 0.10 0.37 CTV Mean Dose 68.30 ± 0.29 Gy 67.68 ± 0.27 Gy -0.9078% 0.019 0.72 CTV Percent Volume Covered by the 95% Isodose Line 100% 100% 0% N/A N/A PTV Min Dose 64.42 ± 0.29 Gy 64.42 ± 0.29 Gy 0% 0.10 0.37 PTV Max Dose 71.78 ± 0.29 Gy 71.76 ± 0.33 Gy -0.02786% 0.94 0.051 PTV Mean Dose 68.39 ± 0.38 Gy 67.94 ± 0.28 Gy -0.6580% 0.063 0.47 PTV Percent Volume Covered by the 95% Isodose Line 100% 100% 0% N/A N/A Body V5 (27.0 ± 1.0)% (26.5 ± 1.0)% -1.85% 2.2 × 10-3 0.96 Global Max Dose 71.80 ± 0.38 Gy 71.76 ± 0.33 Gy -0.05571% 0.89 0.052 Arc 1 Monitor Units 325 ± 17 MU 311.8 ± 9.8 MU -4.06% 0.41 0.12 Arc 2 Monitor Units 330 ± 15 MU 312 ± 10 MU -5.5% 0.19 0.24 Conformity Index 1.127 ± 0.013 1.091 ± 0.015 -3.194% 6.8 × 10-4 0.99 Integral Dose 207 ± 12 Gy·L 191 ± 11 Gy·L -7.73% 1.1 × 10-5 1.0 CTV = Clinical Target Volume; N/A = not applicable for that category; PTV = Planning Target Volume cases had lower MU when using 10 MV, and for the number of MU for the second arc, eight of the ten cases had lower MU when using 10 MV. For the Global Max Dose, six of the ten cases had low­er Global Max Dose when using 10 MV. Further analysis of our power results are presented in the Discussion section below. Discussion Our results have shown that using 10 MV photons instead of 6 MV photons for irradiation of the pros­tate bed will result in statistically significant low­er values for the OAR dose constraint categories, Body V5, Conformity Index, and Integral Dose. We also observed that using 10 MV results in 95% of the prescription dose of 66.6 Gy covering 100% of the CTV and PTV volumes for all ten patients; this is the same coverage as using 6 MV for all ten pa­tients. This is important because OAR dose spar­ing should not occur at the expense of tumor target coverage. It should be noted that the mean results for both 6 MV and 10 MV plans were well below the dose constraints outlined in the RTOG 0534 protocol and posted in Table 1 above. RTOG 0534 was de­veloped as a phase 3 trial for androgen deprivation with pelvic lymph node or prostate bed only ra­diation therapy after a prostatectomy. We used this protocol for our study because it is used at Roswell Park Cancer Institute for plan evaluation when us­ing 6 MV for post-prostatectomy prostate bed ir­radiation. For our study, we used a sample size of ten cases. Even though this is a small sample size, there is no minimum size requirement in using a paired Student t test. Research in the methodol­ogy of statistical testing has shown that a possible limitation for using a small sample size exists in the power of the statistical test that was performed.26,27 However, it has also been shown that this limita­tion regarding small sample sizes does not exist for experiments where there is a large effect size pre­sent.28 For our study, the null hypothesis is that for each category listed above in Table 2, the difference between the respective means for 6 MV and 10 MV are 0. The alternative hypothesis is that there is a difference between the respective means for 6 MV and 10 MV. The probability of committing a Type II error is the probability of failing to reject a false null hypothesis, and is denoted by b. The probabil­ity of rejecting a false null hypothesis is known as the power of the statistical test, and is denoted by 1–b. Looking at our power results in Table 2, we see that for the categories where the p-values are statistically significant, there is a high probabil­ity that we will reject a false null hypothesis, and therefore will not commit a Type II error. Another issue is the possibility of committing a Type I error. The probability of committing a Type I error is the probability of rejecting a true null hypothesis, and is denoted by a. By setting a = 0.05, and obtaining a p-value less than or equal to 0.05 means that there is a high probability (greater than or equal to 95%) that we will not commit a Type I error. In making a comparison between the 6 MV and 10 MV plans used for this study, it should be noted that the 6 MV and 10 MV cases were created by different planners. The 6 MV cases were created by an experienced dosimetrist, while the 10 MV cases were created by a non-experienced planner. This can introduce some biases regarding the 10 MV plan outcomes. However, looking at the 10 MV re­sults, we argue that if the same 6 MV planner had worked on the 10 MV plans, the same or better re­sults could be obtained due to planner experience. The 6 MV plans were created with time constraints imposed by real-world clinical conditions; this was not the case for the 10 MV plans. However, it can be argued that 10 MV plans with the same or bet­ter outcomes could be created by an experienced dosimetrist using the same time constraints as the 6 MV plans. Our results for OAR dose sparing contrast with other studies of IMRT treatment plans using high­er photon beam energies for intact prostate where there is no improvement in dose reduction to OAR and no better Conformity Index.9,11,13 Work done by Pirzkall et al. has shown that when the number of IMRT static fields are increased, the effects of using higher photon energy are downplayed.13 This same study wondered if higher photon energies would play less of a role in rotational IMRT, i.e. VMAT. Studies performed by Pasler et al.12 and Ost et al.29 looked at VMAT planning for prostate cancer for ten and twelve patients, respectively. The study by Pasler et al. found that using photon energies of 10 MV and 15 MV versus 6 MV resulted in a statis­tically significant lower Integral Dose; however, monitor units were not investigated in that study. The study by Ost et al. found that using 18 MV in­stead of 6 MV resulted in statistically significant lower monitor units; however, Integral Dose was not investigated in that study. Furthermore, a recent study by Mattes et al. us­ing 6 MV and 10 MV with VMAT to treat intact prostate cancer also found a lower Conformity Index, lower Integral Dose, and lower monitor units, while having minimal dose sparing to the OAR.30 However, that VMAT study purposely uses the same optimization constraints for both 6 MV and 10 MV treatment plans, thereby not allowing the optimizer to make full use of the 10 MV pho­tons. It can be argued that using 10 MV may allow the optimizer in the Eclipse treatment planning system more leeway to shift more dose from the OAR. Therefore, setting higher dose constraints on the optimization structures may prove useful. In that same study, 10 MV resulted in a more than 16% decrease in maximum dose to the skin struc­ture. While our work did not measure dose to the skin, the possibility of lower skin dose would be another benefit to using 10 MV photons due to the greater penetrating power and longer dose build­up of 10 MV. Skin sparing effects have been noted in a study by Chow et al. of prostate irradiation us­ing IMRT.31 This topic could be investigated in a future work. For our study, most of the OAR dose constraint categories that exhibited the largest dose reduction of more than 10% were to the shallow OAR, i.e. the left and right femoral heads. It stands to rea­son that using 10 MV photons can result in large dose reductions to OAR that are shallowly located relative to the tumor target. Other cancer sites that one may wish to investigate should possess deep seated target volumes. This ensures that much of the dose is deposited into the target, and not to ad­jacent healthy tissue. Therefore, cancers located in the pelvic or abdominal regions should be investi­gated into whether using 10 MV photons provide similar benefits. Another possible benefit for using 10 MV rather than 6 MV could be the reduced chance of a pa­tient having a secondary cancer malignancy. Work done by Kry et al. has shown that the lifetime risk of developing a fatal secondary cancer is 39% higher when using 6 MV compared to 10 MV for IMRT.32 It is possible that this finding carries over into VMAT when using 10 MV instead of 6 MV. A system that tracks future occurrences of cancer in patients treated with prostate bed irradiation may prove useful for future studies. 237 Conclusions In this retrospective study of treatment plans com­paring 6 MV to 10 MV for post-prostatectomy ir­radiation of the prostate bed, we have shown that using 10 MV photons can result in statistically significant better outcomes for our OAR dose con­straints, Body V5, Conformity Index, and Integral Dose. We also have shown that 10 MV can be used in our treatment plans without compromising dose coverage to the CTV and PTV. In addition, neutron contamination from the linac head is not a major concern when choosing 10 MV over 6 MV. From these observations, it can be argued that using 10 MV rather than 6 MV can result in better treatment plans for patients undergoing prostate bed irradia­tion after a prostatectomy. References 1. Laughlin JS, Mohan R, Kutcher GJ. Choice of optimum megavoltage for ac­celerators for photon beam treatment. Int J Radiat Oncol 1986; 12: 1551-7. 2. NCRP. Report No. 79: Neutron contamination from medical electron accel­erators. Bethesda, Maryland: NCRP; 1987. 3. Westermark M, Arndt J, Nilsson B, Brahme A. Comparative dosimetry in narrow high-energy photon beams. Phys Med Biol 2000; 45: 685-702. 4. Howell RM, Ferenci MS, Hertel NE, Fullerton GD. Investigation of secondary neutron dose for 18 MV dynamic MLC IMRT delivery. Med Phys 2005; 32: 786-93. 5. Xu N, Rossi PJ, Jani AB. Toxicity analysis of dose escalation from 75.6 gy to 81.0 gy in prostate cancer. Am J Clin Oncol 2011; 34: 11-5. 6. Zelefsky MJ, Yamada Y, Fuks Z, Zhang Z, Hunt M, Cahlon O, et al. Long-term results of conformal radiotherapy for prostate cancer: impact of dose esca­lation on biochemical tumor control and distant metastases-free survival outcomes. Int J Radiat Oncol 2008; 71: 1028-33. 7. Soderstrom S, Eklof A, Brahme A. Aspects on the optimal photon beam energy for radiation therapy. Acta Oncol 1999; 38: 179-87. 8. Park JM, Choi CH, Ha SW, Ye SJ. The dosimetric effect of mixed-energy IMRT plans for prostate cancer. J Appl Clin Med Phys 2011; 12: 3563. 9. Sun M, Ma L. Treatments of exceptionally large prostate cancer patients with low-energy intensity-modulated photons. J Appl Clin Med Phys 2006; 7: 43-9. 10. Sung W, Park JM, Choi CH, Ha SW, Ye SJ. The effect of photon energy on intensity-modulated radiation therapy (IMRT) plans for prostate cancer. Radiat Oncol J 2012; 30: 27-35. 11. de Boer SF, Kumek Y, Jaggernauth W, Podgorsak MB. The effect of beam energy on the quality of IMRT plans for prostate conformal radiotherapy. Technol Cancer Res Treat 2007; 6: 139-46. 12. Pasler M, Georg D, Wirtz H, Lutterbach J. Effect of photon-beam energy on VMAT and IMRT treatment plan quality and dosimetric accuracy for advanced prostate cancer. Strahlenther Onkol 2011; 187: 792-8. 13. Pirzkall A, Carol MP, Pickett B, Xia P, Roach M, 3rd, Verhey LJ. The effect of beam energy and number of fields on photon-based IMRT for deep-seated targets. Int J Radiat Oncol 2002; 53: 434-42. 14. Welsh JS, Mackie TR, Limmer JP. High-energy photons in IMRT: uncertainties and risks for questionable gain. Technol Cancer Res Treat 2007; 6: 147-9. 15. Palma D, Vollans E, James K, Nakano S, Moiseenko V, Shaffer R, et al. Volumetric modulated arc therapy for delivery of prostate radiotherapy: comparison with intensity-modulated radiotherapy and three-dimensional conformal radiotherapy. Int J Radiat Oncol 2008; 72: 996-1001. 16. Wolff D, Stieler F, Welzel G, Lorenz F, Abo-Madyan Y, Mai S, et al. Volumetric modulated arc therapy (VMAT) vs. serial tomotherapy, step-and-shoot IMRT and 3D-conformal RT for treatment of prostate cancer. Radiother Oncol 2009; 93: 226-33. 17. Shaffer R, Morris WJ, Moiseenko V, Welsh M, Crumley C, Nakano S, et al. Volumetric modulated Arc therapy and conventional intensity-modulated radiotherapy for simultaneous maximal intraprostatic boost: a planning comparison study. Clin Oncol 2009; 21: 401-7. 18. Zhang P, Happersett L, Hunt M, Jackson A, Zelefsky M, Mageras G. Volumetric modulated arc therapy: planning and evaluation for prostate cancer cases. Int J Radiat Oncol 2010; 76: 1456-62. 19. Cozzi L, Dinshaw KA, Shrivastava SK, Mahantshetty U, Engineer R, Deshpande DD, et al. A treatment planning study comparing volumetric arc modulation with RapidArc and fixed field IMRT for cervix uteri radiotherapy. Radiother Oncology 2008; 89: 180-91. 20. Guckenberger M, Richter A, Krieger T, Wilbert J, Baier K, Flentje M. Is a single arc sufficient in volumetric-modulated arc therapy (VMAT) for complex-shaped target volumes? RadiotherOncol 2009; 93: 259-65. 21. NCRP. Report No. 151: Structural shielding design and evaluation for mega-voltage x-and gamma-ray radiotherapy facilities. Bethesda, Maryland: NCRP; 2006. 22. RTOG. RTOG 0534: A phase III trial of short term androgen deprivation with pelvic lymph node or prostate bed only radiotherapy (spport) in prostate cancer patients with a rising psa after radical prostatectomy. Philadelphia, Pennsylvania: RTOG; 2013. 23. ICRU. Report No. 62: Prescribing, recording and reporting photon beam therapy (supplement to ICRU report 50). Bethesda, Maryland: ICRU; 1999. 24. R Core Team. R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing; 2015. 25. Skwarchuk MW, Jackson A, Zelefsky MJ, Venkatraman ES, Cowen DM, Levegrun S, et al. Late rectal toxicity after conformal radiotherapy of pros­tate cancer (I): multivariate analysis and dose-response. Int J Radiat Oncol 2000; 47: 103-13. 26. Rossi JS. Statistical power of psychological research: What have we gained in 20 years? J Consult Clin Psych 1990; 58: 646-56. 27. Cohen J. Approximate power and sample size determination for common one-sample and two-sample hypothesis tests. Educ Psychol Meas 1970; 30: 811-31. 28. de Winter JC. Using the Student’s t-test with extremely small sample sizes. Practical Assessment, Research & Evaluation 2013; 18: 1-12. 29. Ost P, Speleers B, De Meerleer G, De Neve W, Fonteyne V, Villeirs G, et al. Volumetric arc therapy and intensity-modulated radiotherapy for primary prostate radiotherapy with simultaneous integrated boost to intraprostatic lesion with 6 and 18 MV: a planning comparison study. Int J Radiat Oncol 2011; 79: 920-6. 30. Mattes MD, Tai C, Lee A, Ashamalla H, Ikoro NC. The dosimetric effects of photon energy on the quality of prostate volumetric modulated arc therapy. Pract Radiat Oncol 2014; 4: e39-44. 31. Chow JC, Grigorov GN, Barnett RB. Study on surface dose generated in pros­tate intensity-modulated radiation therapy treatment. Med Dosim 2007; 31: 249-58. 32. Kry SF, Followill D, White RA, Stovall M, Kuban DA, Salehpour M. Uncertainty of calculated risk estimates for secondary malignancies after radiotherapy. Int J Radiat Oncol 2007; 68: 1265-71. research article Effect of photon energy spectrum on dosimetric parameters of brachytherapy sources Mahdi Ghorbani1, Mohammad Mehrpouyan2, David Davenport3, Toktam Ahmadi Moghaddas4 1 Medical Physics Research Center, Mashhad University of Medical Sciences, Mashhad, Iran 2 Bioinformatics Research Center, Sabzevar University of Medical Sciences, Sabzevar, Iran 3 Comprehensive Cancer Centers of Nevada, Las Vegas, Nevada, USA 4 Department of Basic Medical Sciences, Neyshabur University of Medical Sciences, Neyshabur, Iran Radiol Oncol 2016; 50(2): 238-246. Received 2 November 2015 Accepted 29 January 2016 Correspondence to: Mohammad Mehrpouyan, Bioinformatics Research Center, Sabzevar University of Medical Sciences, Sabzevar, Iran. Phone: +98 51 4444 6070, +98 51 4444 6234; Fax: +98 51 4444 5648; E-mail: mehrpouyan.mohammad@gmail.com; or Toktam Ahmadi Moghaddas, Department of Basic Medical Sciences, Neyshabur University of Medical Sciences, Neyshabur, Iran. E-mail: toktamt.moghadas@gmail.com Disclosure: No potential conflicts of interest were disclosed. Aim. The aim of this study is to quantify the influence of the photon energy spectrum of brachytherapy sources on task group No. 43 (TG-43) dosimetric parameters. Background. Different photon spectra are used for a specific radionuclide in Monte Carlo simulations of brachy­therapy sources. Materials and methods. MCNPX code was used to simulate 125I, 103Pd, 169Yb, and 192Ir brachytherapy sources. Air kerma strength per activity, dose rate constant, radial dose function, and two dimensional (2D) anisotropy functions were calculated and isodose curves were plotted for three different photon energy spectra. The references for pho­ton energy spectra were: published papers, Lawrence Berkeley National Laboratory (LBNL), and National Nuclear Data Center (NNDC). The data calculated by these photon energy spectra were compared. Results. Dose rate constant values showed a maximum difference of 24.07% for 103Pd source with different photon energy spectra. Radial dose function values based on different spectra were relatively the same. 2D anisotropy function values showed minor differences in most of distances and angles. There was not any detectable difference between the isodose contours. Conclusions. Dosimetric parameters obtained with different photon spectra were relatively the same, however it is suggested that more accurate and updated photon energy spectra be used in Monte Carlo simulations. This would allow for calculation of reliable dosimetric data for source modeling and calculation in brachytherapy treatment planning systems. Key words: photon energy spectrum; brachytherapy; TG-43 dosimetric parameters; dose distribution Introduction Monte Carlo (MC) codes are currently used to verify brachytherapy sources while utilizing the photon energy spectrum of a specific radionuclide for calculations. There exist some common energy spectrum databases which are used by researchers. Some use the recommendation of the American Association of Physicists in Medicine (AAPM) from task group No. 43 updated report (TG-43 U1) which was prepared for low energy photon emit­ting radionuclides such as 125I and 103Pd.1 In a re­port by the AAPM and the European Society for Therapeutic Radiology and Oncology (ESTRO)2, the use of the energy spectrum database of the National Nuclear Data Center (NNDC)3 was rec­ 239 ommended for photon emitting radionuclides higher than 50 keV. There are various methods to determine the energy spectra of photon emitting radionuclides. One widely used technique is high-purity germa­nium detectors, especially for low energy sourc­es.4-6 Chen et al.7, have used a high purity ger­manium detector to measure the photon energy spectrum emitted by a 125I brachytherapy source. Rivard et al.8 have studied the influence of photon energy spectrum on kerma and dose rate for 125I, 103Pd, and 192Ir sources. They calculated the water kerma proportion for each photon energy to the total energy and plotted the obtained data for dif­ferent distances. It was concluded that the differ­ences in photon energy spectra do not have a con­siderable impact on the dose rate constant because of the compensatory effect of dividing dose rate to air kerma strength. In a study by Aryal et al.9, TG­43 dosimetry parameters were calculated for IAI 125I brachytherapy source by variation of some fac­tors such as photon energy spectrum. They found that the photon energy spectrum can change dose rate constant by up to 3% and can alter radial dose function about 12% (at r = 10 cm where the dose rate is very low). It is necessary to implement TG-43 dosimetric 125I parameters in treatment planning systems.10 brachytherapy source models are widely used in prostate cancer treatments wherein the dose re­ceived by organs at risk such as rectum and uri­nary bladder is important. To quantify the dose to these organs, treatment planning systems use the appropriate TG-43 dosimetric parameters which were reported in the literature. Treatment plan­ning systems do not use energy spectrum directly, but they use TG-43 parameters reported by a pub­lished study. Therefore, the energy spectrum used in that study can effect on the calculation accuracy of the treatment planning systems indirectly. So the precision of energy spectrum of the radionu­clide can have influences on the calculated dose to the tumor and the related organs at risk. Therefore, it is important to provide accurate energy spec­tra of radionuclides. In the previously mentioned studies, only some dosimetric parameters were evaluated from the energy spectrum point of view. To the best of our knowledge, a comprehensive study considering the influence of photon energy spectrum on the dosimetric parameters of brachy­therapy sources was not performed. The aim of this study is to evaluate the influence of photon energy spectrum on TG-43 dosimetric parameters and isodose curves for three common photon energy spectra; for 125I, 103Pd, 169Yb, and 192Ir brachytherapy sources. Materials and methods In this study, MCNPX code (version 2.4.0) was used to simulate brachytherapy sources.11 Four brachytherapy sources were studied: MED 3631­A/M 125I, Optiseed 103Pd, a hypothetical 169Yb, and Flexisource 192Ir sources. In the selection of these ra­dionuclides, there was an attempt to evaluate vari­ous brachytherapy sources within a relatively wide range of photon energies. The MED 3631-A/M 125I source consists of four polystyrene spheres coated with active 125I with an active length of 4.2 mm. The Optiseed 103Pd is composed of two polystyrene cyl­inders containing active 103Pd. The active length of 103Pd is assumed to be 3.8 mm. The 169Yb and 192Ir sources have the same geometries with 3.5 mm ac­tive core, including radioactive 169Yb and 192Ir, re­spectively. The geometry properties of simulated sources were described in details in the previous published article.12 The simulations of the sources were verified in that study and the same input files were applied for the mentioned brachytherapy sources in the current study. In that study12 the ver­ification was based on calculation and comparison of dose rate constant and radial dose function with the corresponding published data on these source models. Dosimetric parameters The updated report of TG-43U11 was followed to calculate the dosimetric parameters of low energy brachytherapy sources. For higher energy brachy­therapy sources the recommendations by the re­port of AAPM and ESTRO2 were applied. Based on the report of TG-43 U1, dose rate is calculated from the following formula: [1] Geometry function with line-source approxima­tion (GL(r, .)), radial dose function (gL(r, .)) and two dimensional (2D) anisotropy function (F(r, .)) are calculated from the following formulas: [2] [4] where ß is the angle between the tips of the ends of the active part of source and point of calculation; L is the active length of the source; r is the radial dis­tance from the source and the calculation point; and . is the polar angle specifying the calculation point. Monte Carlo simulations MCNPX code (version 2.4.0) was used for the simu­lations. MCNPX is a general purpose Monte Carlo code and is able to transport neutrons, photons, elec­trons and other particles in various geometries. It in­cludes a geometry modeling tool and various tallies related to energy deposition, particle current, and particle flux. The 2.4.0 version of this code, which was used in the present study, uses MCPLIB02 cross section library for transport of photons.13-14 In the MC calculations both photons and electrons were transported. Line-source approximation was used in the MC simulations. The energy cut-off for pho­tons and electrons was considered 1 keV for 125I and 103Pd sources and 5 keV for 169Yb and 192Ir sources in all input files. No other variance reduction method was applied in this study. To calculate air kerma strength, air toroid cells were defined in a 100 cm radius vacuum sphere. The brachytherapy source was located at the center of this sphere. The torus cells were in the range of 1–50 cm and their thickness was assumed 1 mm. An F6 tally was scored in these torus cells and the out­puts were multiplied by r2 (where r is the distance from the center of the source). There are different tallies in MCNP (including F4, *F4, F6, etc.) which can be utilized to score various dosimetric param­eters such as particle flux, energy flux, kerma, etc. In various versions of MCNP code F6 tally is used to score energy deposition averaged over a cell in terms of MeV/g per particle11. In other words, kerma is calculated by this tally type. The average of F6 × r2 versus r on the flat region of the curve was calculated to obtain air kerma strength. After obtaining air kerma strength, its value per mCi was calculated for each photon energy spectrum and source. The number of particles transported was 5 × 107 and type A statistical uncertainty was less than 1.4% in this step. To obtain the dose rate constant, an *F4 tally was calculated at r0 = 1 cm and .0 = ./2. *F4 tally is en­ [3] ergy flux of a particle type averaged over a cell (in terms of MeV/cm2).11 It should be noticed that with F4 and *F4 tallies in MCNP, it is possible to score particle flux and energy flux in a cell, respectively. In other words, the asterisk sign determines that energy flux be scored by the code, and not particle flux. The outputs of this tally were multiplied by mass energy absorption coefficients at various en­ergy bins and the dose was obtained. The dose was divided to air kerma strength value for each source. Additionally, the dose rate at r = 1 cm per mCi for each photon energy spectrum and each source was calculated. Radial dose function was calculated in 1 mm thickness torus cells at radial distances of 0.5–15 cm in a spherical water phantom. The phan­tom radius was assigned 50 cm and an *F4 tally was scored and then converted to dose. The num­ber of particle histories for the dose rate constant and radial dose function calculations was 108 for 125I, 169Yb, and 192Ir and 3 × 108 for 103Pd source. The maximum type A statistical uncertainty was 4.16%. The 2D anisotropy function was calculated at 0°–180° with a degree interval of 10° at radial dis­tances of 0.5, 1, 5, 10, and 15 cm. The source was located at the center of a spherical water phantom with a 50 cm radius and an *F4 tally was calculated. Spherical cells were used for 0 ° and 180 ° polar an­gles while torus cells were defined for the other po­lar angles. The number of particles for this section was assumed as 2 × 108 for 169Yb and 192Ir sources; 9 × 108 for 125I source; and 2 × 109 for 103Pd source. In all of the data points, the Type A statistical uncer­tainty was less than 4.18%, with exceptions for two points with 13.8% uncertainty at 0o and 180o angles in 15 cm distance for the 103Pd source. These un­certainties could not be reduced because it was not possible to exceed the maximum particle history of 2 × 109 in MCNP. To plot isodose curves for a source, a mesh grid was defined in a 50 cm spherical water phantom. The sources were defined in the phantom, separate­ly. For the purpose of output calculation, “pedep” option of type 1 mesh tally type in MCNP was ap­plied in the grid. In MCNP, there are various mesh tallies (including type 1, type 2, type 3, etc.) which can be used to score different dosimetric variables in a grid. Each mesh tally has various options, by which the user defines that which variable should be scored by the code. As an example, type 1 tally is track-average mesh tally. With “pedep” option in this mesh tally type, the average energy deposition per unit volume (in terms of MeV/cm per source particle) for a specified particle type is calculated. This option allows the user to score the equivalent of F6 tally. The grid included 2 × 2 × 2 mm3 and the obtained data was plotted in the Y-Z plane using MATLAB software (version: 8.3.0.532, The Mathworks, Inc., Natwick, MA).15 The number of particles for 125I, 169Yb, and 192Ir sources was 6 × 108 photons while it was 1.5 × 109 for the 103Pd source. The type A statistical uncertainty in these mesh voxels was less than 6.5% in the output files. The effect of photon energy spectrum The effect of energy spectrum on dosimetric pa­rameters of 125I, 103Pd, 169Yb, and 192Ir radionu­clides was evaluated for three different spectra. As the first spectrum and via a common method in brachytherapy Monte Carlo studies, the re­ported photon energy spectra by previous papers were used for the radionuclides.1,16-18 As the second spectrum database, Lawrence Berkeley National Laboratory (LBNL) was chosen.19 We applied ver­sion 2.1 (January 2004) for all radionuclides in the LBNL database. The third spectrum applied for each radionuclide was extracted from the National Nuclear Data Center (NNDC) database3 as it was suggested by the report of AAPM and ESTRO.2 The NNDC database reports a number of energy spec­tra for a radionuclide. In the present study, these numbers of datasets were chosen from NNDC 242 TABLE 1. Information on photon energy spectra of the 125I and 103Pd, 169Yb, and 192Ir radionuclides reported by different databases Reference TG-43 U11 LBNL19 NNDC20 Rivard16 LBNL19 NNDC21 Energy range (keV) 27.202-35492 3.335-35.4919 3.77­35.4925 22.074-497.054 2.377-497.08 2.7-487.08 Total photons per disintegration 1.4757 1.60482 1.5767 0.7713825 0.851569801 0.857582605 Reference Cazeca et al.17 LBNL19 NNDC22 Medich and Munro18 LBNL19 NNDC23 Energy range (keV) 49.77-307.74 6.341-781.64 7.18-781.64 61.49-884.54 7.822-1378.3 9.44-1378.50 Total photons per disintegration 3.322 3.779 3.771 2.301 2.359 2.214 Average energy (keV) 92.797 82.622 82.781 354.356 346.736 369.525 LBNL = Lawrence Berkeley National Laboratory; NNDC = National Nuclear Data Center; TG-43 U1 = Recommendation of the American Association of Physicists in Medicine from task group No. 43 updated report TABLE 2. Air kerma strength, dose rate constant, and dose rate at 1 cm for 125I, 103Pd, 169Yb, and 192Ir sources based on different photon energy spectra reported by other studies, LBNL, and NNDC databases 103Pd 1.132 1.428 1.404 -19.37 1.71 169Yb 1.094 1.094 1.097 -0.27 -0.27 192Ir 3.622 3.631 3.496 3.60 3.86 103Pd 0.830 0.658 0.669 24.06 -1.64 169Yb 1.222 1.226 1.222 0.00 0.33 192Ir 1.117 1.117 1.117 0.00 0.00 125I 1.154 1.123 1.136 1.60 -1.07 103Pd 0.939 0.940 0.939 0.00 0.09 169Yb 1.338 1.341 1.341 -0.23 0.00 192Ir 4.045 4.054 3.904 3.59 3.84 LBNL = Lawrence Berkeley National Laboratory; NNDC = National Nuclear Data Center database: dataset No. 1 for 125I20, dataset No. 1 for 103Pd21, dataset No. 2 for 169Yb22 and dataset No. 4 for 192Ir23 radionuclides. The photon energy spectra of 125I, 103Pd, 169Yb, and 192Ir radionuclides reported by various data­bases are listed in Table 1. The photon energy spec­tra applied for the 125I source are: AAPM TG-43 U1 report1, LBNL database19, and NNDC database.20 For the 103Pd source, the photon energy spectra reported by a study by Rivard16, LBNL database19, and NNDC database21 were used. The photon en­ergy spectra applied for the 169Yb source are: the study by Cazeca et al.17, LBNL database20, and NNDC database.22 For the 192Ir source, we extracted the photon energy spectra reported by Medich and Munro18, LBNL database19, and NNDC database.23 In MCNPX code, the photon energy spectrum should be introduced for a source in terms of ener­gies of photons (MeV) emitted by the radionuclide and their intensities. For the four sources, it was 243 TABLE 3. Radial dose function for 125I, 103Pd, 169Yb, and 192Ir sources based on different photon energy spectra reported by other studies1,16-18, Lawrence Berkeley National Laboratory (LBNL)19, and National Nuclear Data Center (NNDC)20-23 databases 0.5 0.996 0.996 0.996 0.00 0.00 1.196 1.196 1.196 0.00 0.00 1 1.000 1.000 1.000 0.00 0.00 1.000 1.000 1.000 0.00 0.00 1.5 0.955 0.955 0.954 0.11 0.10 0.789 0.789 0.789 0.00 0.00 2 0.890 0.890 0.890 0.00 0.00 0.609 0.609 0.608 0.16 0.16 2.5 0.816 0.815 0.816 0.00 -0.12 0.465 0.465 0.464 0.22 0.22 3 0.740 0.740 0.740 0.00 0.00 0.352 0.352 0.352 0.00 0.00 3.5 0.667 0.666 0.667 0.00 -0.15 0.265 0.265 0.264 0.38 0.38 4 0.596 0.596 0.595 0.17 0.17 192 Ir 103 Pd 0.199 0.199 0.198 0.50 0.51 0.150 0.150 0.149 0.67 0.68 169 Yb 125 I 4.5 0.530 0.530 0.530 0.00 0.00 5 0.470 0.469 0.470 0.00 -0.21 0.112 0.112 0.112 0.00 0.00 5.5 0.415 0.415 0.415 0.00 0.00 0.084 0.084 0.083 1.20 1.21 6 0.365 0.365 0.365 0.00 0.00 0.063 0.062 0.062 1.61 0.00 6.5 0.320 0.319 0.319 0.31 0.00 0.047 0.047 0.047 0.00 0.00 7 0.279 0.279 0.279 0.00 0.00 0.035 0.035 0.035 0.00 0.00 10 0.120 0.120 0.120 0.00 0.00 0.0066 0.0066 0.0065 1.54 1.54 15 0.029 0.029 0.029 0.00 0.00 0.0010 0.0010 0.0010 0.00 0.00 0.5 0.950 0.949 0.951 -0.11 -0.21 0.996 0.996 0.996 0.00 0.00 1 1.000 1.000 1.000 0.00 0.00 1.000 1.000 1.000 0.00 0.00 1.5 1.042 1.041 1.041 0.10 0.00 1.003 1.003 1.003 0.00 0.00 2 1.079 1.079 1.077 0.19 0.19 1.006 1.006 1.006 0.00 0.00 2.5 1.113 1.111 1.110 0.27 0.09 1.008 1.008 1.008 0.00 0.00 3 1.136 1.137 1.133 0.27 0.35 1.010 1.010 1.009 0.10 0.10 3.5 1.157 1.156 1.155 0.17 0.09 1.011 1.011 1.010 0.10 0.01 4 1.169 1.171 1.168 0.09 0.26 4.5 1.183 1.181 1.180 0.25 0.09 1.011 1.011 1.010 0.10 0.10 1.010 1.010 1.010 0.00 0.00 5 1.189 1.185 1.185 0.34 0.00 1.008 1.008 1.007 0.10 0.10 5.5 1.193 1.191 1.191 0.17 0.00 1.005 1.005 1.005 0.00 0.00 6 1.195 1.189 1.190 0.42 -0.08 1.002 1.002 1.001 0.10 0.10 6.5 1.189 1.185 1.186 0.25 -0.08 0.998 0.998 0.998 0.00 0.00 7 1.182 1.181 1.181 0.09 0.00 0.995 0.994 0.994 0.10 0.00 10 1.089 1.091 1.090 -0.09 0.09 0.949 0.949 0.949 0.00 0.00 15 0.860 0.865 0.862 -0.23 0.35 0.836 0.836 0.835 0.12 0.12 not feasible to list all the energies and the related TG-43 parameters were calculated for 125I, 103Pd, probabilities in a single table or figure. Therefore, 169Yb, and 192Ir sources with three specific photon some information including the energy range, total energy spectra to evaluate whether the photon en-intensity, and average energy are listed in Table 1. ergy spectrum effect the dosimetric parameters. FIGURE 3. Isodose curves for (A) 125I, (B) 103Pd, (C) 169Yb, and (D) 192Ir sources obtained by different photon energy spectra. The contours for various spectra are not clearly distinguishable due to their overlapping. Results The values of air kerma strength per activity were calculated for MED 3631-A/M 125I, Optiseed 103Pd, a hypothetical 169Yb, and Flexisource 192Ir sources. These values are presented in Table 2 for three photon energy spectra for each of these sources. Furthermore, dose rate constant and dose rate at r = 1 cm are presented in Table 2. The values of ra­dial dose function at r = 0.5–15 cm with the three photon energy spectra for 125I, 103Pd, 169Yb, and 192Ir sources are listed in Table 3. 2D anisotropy function calculated at . = 0°– 180° angles for r = 0.5, 5, and 15 cm distances for 125I, 103Pd, 169Yb, and 192Ir sources are illustrated in Figure 1. The differences between the anisot­ropy function data based on NNDC photon en­ergy spectrum and the other spectra are shown in Figure 2. The isodose curves for 125I, 103Pd, 169Yb, and 192Ir sources based on different energy spectra reported by articles1,16-18, LBNL19 and NNDC20-23 are contoured in Figure 3. In this figure the dose values are related to the values in the Z-X plane while the source’s longitudinal axis is along the Z- axis. The dose values are normalized to the dose at r = 1 cm for each source. Discussion In the current study, the influence of photon en­ergy spectrum on dosimetric parameters of 125I, 103Pd, 169Yb, and 192Ir brachytherapy sources was evaluated. Dose rate constant is the ratio of dose rate at 1 cm to air kerma strength. All these quan­tities are presented in Table 2 for the considered sources. The relative difference values of dose rate constant with regard to NNDC based data, shows a maximum value of 24.06% and 10.07% for the 103Pd and 125I brachytherapy sources, respectively (Table 2). These percentage differences are related to the photon energy spectra by TG-43 U1 proto­col1 and NNDC20 database for the 125I source; and LBNL19 and NNDC database21 for the 103Pd source. There are non-negligible differences between the dose rate constant values obtained by different photon energy spectra databases for the 125I and 103Pd sources. Table 2 demonstrates that the cause of these differences is due to air kerma strengths. The effect for air kerma strength to the differenc­es in total number of photons per disintegration (Table 1) and the differences in photon energy in various spectra demonstrate their main cause is air kerma strength. In other words, for calculation of air kerma strength the environment is void and minor differences in photon energy have a major effect on the kerma rate. This effect is not seen for dose rate at 1 cm in which the media is water. The radial dose function calculated by different photon energy spectra does not show a consider­ 245 able difference between brachytherapy sources. The differences do not show a general trend with distance. The minor effect of energy spectrum on radial dose function is in agreement with the re­sults by Rivard et al.8 In that study, the effect of energy spectrum on dose rate constant and radial dose function ranged from 0.1% to 2%. The val­ues of anisotropy function illustrated in Figure 1 show a similar trend for all applied photon energy spectra of brachytherapy sources. As illustrated in Figure 2, there are some points that a non-negli­gible difference is observable. This figure refers a larger difference at . = 0° and 180° at far distances from the 103Pd, 125I and 169Yb sources, respectively. Furthermore, as it can be seen from the range of vertical axis of Figure 2, the difference of anisot­ropy function values with regard to the values calculated by NNDC spectra databases, 103Pd, 125I, and 169Yb show the maximum differences. For the 103Pd source, about 35% difference was observed between anisotropy function calculated based on the photon energy spectra reported by LBNL and NNDC databases. The reason for the differences in the 0° and 180° degrees for 103Pd is related to the un­certainty in the Monte Carlo calculations (13.8%), therefore they may be independent of the effect of photon spectrum. In the current study no variance reduction method was applied except for energy cut offs. For future studies, it is suggested to apply such methods to reduce the statistical uncertain­ties, especially for the 103Pd source. As it is seen in Figure 3, there is no observable difference in isodose curves of 125I, 103Pd, 169Yb, and 192Ir sources with different photon energy spectra. However, this doesn’t mean that the photon energy spectrum choice for a radionuclide doesn’t affect dose distribution around the source. As it was im­plied from the obtained data of TG-43 dosimetric parameters, such as air kerma strength and dose rate constant values, this effect is not negligible. On the other hand, isodose contours cannot show such differences. Relying only on isodose curves for clinical application of brachytherapy sources may induce some errors in quantification of dose values. For different photon energy spectra the cal­culated mean energies were in relatively good agreement for both LBNL and NNDC databases. A maximum of 24.06% difference was observed between dose rate constant of different energy da­tabases. Ignoring the differences in the anisotropy function values at . = 0° and 180° degrees, espe­cially for the 103Pd source which originate from the Monte Carlo calculation uncertainties, there are minor differences in dosimetric parameters of the studied sources for various energy spectrum ref­erences. Additionally no considerable difference was observed in isodose curves of different pho­ton energy spectra. Generally it can be concluded that while these differences are not considerable, due the fact that the total uncertainty in dose deliv­ery in radiotherapy should not exceed ±5% (ICRU report No. 2424), it is recommended that more ac­curate and updated photon energy spectrum da­tabases be used in Monte Carlo simulation and other radiotherapy applications of brachytherapy sources. This is to minimize the related uncertain­ties in clinical applications of the sources and is in accordance with the AAPM and ESTRO guideline on simulation of brachytherapy sources.2 Acknowledgment The authors would like to thank Sabzevar University of Medical Sciences for financial sup­port of this work. References 1. Rivard MJ, Coursey BM, DeWerd LA, Hanson WF, Huq MS, Ibbott GS, et al. Update of AAPM task group No. 43 report: a revised AAPM protocol for brachytherapy dose calculations. Med Phys 2004; 31: 633-74. 2. Perez-Calatayud J, Ballester F, Das RK, Dewerd LA, Ibbott GS, Meigooni AS, et al. Dose calculation for photon-emitting brachytherapy sources with average energy higher than 50 keV: Report of the AAPM and ESTRO. Med Phys 2012; 39: 2904-29. 3. National Nuclear Data Center (NNDC); 2007, Available at: http://www.nndc. bnl.gov. [Accessed 22 Jan 2016). 4. Keillor ME, Aalseth CE, Day AR, Fast JE, Hoppe EW, Hyronimus BJ, et al. Design and construction of an ultra-low-background 14-crystal germanium array for high efficiency and coincidence measurements. J Radioanal Nucl Chem 2009; 282: 703-8. 5. Nedera H, Heussera G, Laubensteinb M. Low level .-ray germanium-spec­trometer to measure very low primordial radionuclide concentrations. Appl Radiat Isotopes 2000; 53: 191-5. 6. Karamanis D. Efficiency simulation of HPGe and Si (Li) detectors in .- and X-ray spectroscopy. Nucl Instr Meth Phys Res 2003; 505: 282-5. 7. Chen Z, Bongiorni P, Nath R. Experimental characterization of the dosimetric properties of a newly designed I-Seed model AgX100 125I interstitial brachy­therapy source. Brachytherapy 2012; 11: 476-82. 8. Rivard MJ, Granero D, Perez-Calatayud J, Ballester F. Influence of photon energy spectra from brachytherapy sources on Monte Carlo simulations of kerma and dose rates in water and air. Med Phys 2010; 37: 869-76. 9. Aryal P, Molloy JA, Rivard MJ. A modern Monte Carlo investigation of the TG­43 dosimetry parameters for an 125I seed already having AAPM consensus data. Med Phys 2014; 41: 021702. 10. Luse RW, Blasko J, Grimm P. A method for implementing the American Association of Physicists in Medicine Task Group-43 dosimetry recom­mendations for 125I transperineal prostate seed implants on commercial treatment planning systems. Int J Radiat Oncol Biol Phys 1997; 37: 737-41. 11. Waters LS. MCNPX user ’s manual. Version 2.4.0. Report LA-CP-02-408 (Los Alamos, New Mexico: Los Alamos National Laboratory; 2000. 246 12. Moghaddas TA, Ghorbani M, Haghparast A, Flynn RT, Eivazi MT. A Monte Carlo study on dose enhancement effect of various paramagnetic na­noshells in brachytherapy. J Med Biol Eng 2014; 34: 559-67. 13. Gifford KA, Mourtada F, Cho SH, Lawyer A, Horton JL Jr. Monte Carlo calcu­lations of the dose distribution around a commercial gynecologic tandem applicator. Radiother Oncol 2005; 77: 210-5. 14. Bahreyni Toossi MT, Abdollahi M, Ghorbani M. A Monte Carlo study on dose distribution validation of GZP6 60Co stepping source. Rep Pract Oncol Radiother 2013; 18: 112-6. 15. MathWorks Inc., Available at: http://www.mathworks.com/matlabcentral/. [Accessed 22 Jan 2016]. 16. Rivard MJ. A discretized approach to determining TG-43 brachytherapy dosimetry parameters: case study using Monte Carlo calculations for the MED3633 103Pd source. Appl Radiat Isotopes 2001; 55: 775-82. 17. Cazeca MJ, Medich DC, Munro JJ 3rd. Monte Carlo characterization of a new Yb-169 high dose rate source for brachytherapy application. Med Phys 2010; 37: 1129-36. 18. Medich DC, Munro JJ 3rd. Monte Carlo characterization of the M-19 high dose rate Iridium-192 brachytherapy source. Med Phys 2007; 34: 1999­2006. 19. LBNL Isotopes Project - LUNDS Universitet. Available at: http://ie.lbl.gov/toi/ index.asp. [Accessed 22 Jan 2016]. 20. National Nuclear Data Center (NNDC); 2007. Available at: http://www. nndc.bnl.gov/chart/decaysearchdirect.jsp?nuc=125I&unc=nds. [Accessed 22 Jan 2016]. 21. National Nuclear Data Center (NNDC); 2007. Available at: http://www.nndc. bnl.gov/chart/decaysearchdirect.jsp?nuc=103PD&unc=nds. [Accessed 22 Jan 2016]. 22. National Nuclear Data Center (NNDC); 2007, Available at (http://www.nndc. bnl.gov/chart/decaysearchdirect.jsp?nuc=169YB&unc=nds), [accessed at 22 January 2016]. 23. National Nuclear Data Center (NNDC); 2007. Available at: http://www. nndc.bnl.gov/chart/decaysearchdirect.jsp?nuc=192IR&unc=nds. [Accessed 22 Jan 2016]. 24. International Commission on Radiation Units and Measurements. Determination of absorbed dose in a patient irradiated by beams of X or gamma rays in radiotherapy procedures. Washington, Bethesda: ICRU; 1976. Report No: ICRU-24. Radiol Oncol 2016; 50(2): 129-138. doi:10.1515/raon-2015-0003 Sistemsko zdravljenje malignih gliomov Mesti T, Ocvirk J Izhodišča. Maligni gliomi so hitro napredujoči možganski tumorji z zelo izrazitimi znaki bolezni in visoko smrtnostjo. Do nedav­nega so bile možnosti njihovega zdravljenja omejene in enake za vse podtipe. Zdravili smo jih predvsem kirurško in z radiote­rapijo. Kemoterapijo smo uporabljali kot dopolnilno zdravljenje in ob ponovitvi bolezni; imela je precej omejeno učinkovitost. Zaključki. Tudi danes je zdravljenje malignih gliomov multidisciplinarno ter vključuje kirurgijo, radioterapijo in kemoterapijo. Izbrano zdravljenje je bolj celovito in ga prilagajamo posamezniku. Vpliv na preživetje in kakovost življenja je opazno večji. Radiol Oncol 2016; 50(2): 139-144. doi:10.1515/raon-2015-0004 Zgodnja medicinska rehabilitacija po nevrokirurškem zdravljenju malignih možganskih tumorjev v Sloveniji Kos N, Kos B, Benedičič M Izhodišča. Število bolnikov z malignimi možganskimi tumorji je v porastu. Zaradi novih metod zdravljenja je preživetje daljše. Kljub daljšemu preživetju pa so posledice tumorja in zdravljenja pogosto hude in vplivajo na kakovost bolnikovega življenja. Ustrezna in dovolj zgodaj uvedena rehabilitacija predstavlja pomemben del obravnave bolnikov. Njen najpomembnejši cilj je preprečevanje zapletov, ki lahko imajo negativni vpliv na funkcijske sposobnosti bolnika Zaključki. Z izvajanjem individualno prilagojenih postopkov zgodnje medicinske rehabilitacije je pogosto možno doseči bolnikovo samostojnost pri gibanju in opravljanju osnovnih dnevnih aktivnosti že pred odpustom iz bolnišnice. Potrebno je redno in natančno ocenjevanje bolnikov ob odpustu s ciljem ugotoviti, kateri bolniki poleg onkološkega zdravljenja potre­bujejo tudi kompleksno rehabilitacijsko obravnavo. Pri teh bolnikih lahko z zgodnjo medicinsko rehabilitacijo povečamo možnost dobrega funkcijskega izida. Radiol Oncol 2016; 50(2): 145-152. doi:10.1515/raon-2016-0020 Ob presejanju ugotovljen duktalni rak in situ, odkrit pri stereotaktični vakuumski biopsiji sumljivih mikrokalcinacij brez tumorske formacije. Radiološko-histološka primerjava Szynglarewicz B, Kasprzak P, Biecek P, Halon A, Matkowski R Izhodišča. Mikrokalcinacije, ki jih običajno odkrijemo s presejalno mamografijo, so najpogostejši znak duktalnega raka in situ (DCIS). Cilj raziskave je bil ugotoviti povezavo med klinično-radiološkimi značilnostmi in histološkim rezultatom pri bolnicah z netipnim duktalnim rakom in situ. Bolniki in metode. V raziskavo smo vključili 127 bolnic z netipnim duktalnim rakom in situ, odkritim s stereotaktično vakuum­sko biopsijo sumljivih mikrokalcinacij brez tumorske formacije. Ugotavljali smo starost bolnikov, tip in razporeditev mikrokalci­nacij, stopnjo malignosti in prisotnost komedonekroze. Naredili smo statistično analizo povezanosti posameznih dejavnikov; vrednost P < 0,05 smo upoštevali kot statistično značilno. Rezultati. Mikrokalcinacije v obliki prahu (»powdery«) so bile najpogosteje razvrščene v skupine, medtem ko so bile intra­duktalne polimorfne mikrokalcinacije (»casting-type«) običajno razporejene regionalno (P < 0,001). Visoka, srednja in nizka stopnja malignosti je bila najpogostejša pri intraduktalnih polimorfnih mikrokalcinacijah (»casting«), kalcinacijah v obliki lo­mljenega kamna (»crushed stone-like«) in mikrokalcinacijah v obliki prahu (P < 0,01). Duktalni rak in situ nizke in srednje stopnje malignosti je bil najpogostejši pri mikrokalcinacijah razvrščenih v skupine, medtem ko je bil duktalni rak in situ visoke stopnje malignosti najpogostejši pri regionalni razporeditvi mikrokalcinacij (P < 0,05). Komedonekroza je bila statistično značilno pogo­stejša pri duktalnem raku in situ visoke stopnje malignosti (P < 0,01). Povezava med komedonekrozo in tipom mikrokalcinacij ni bila statistično pomembna, povezava z njihovo razporeditvijo pa je bila blizu meje statistične značilnosti (P = 0,07). Povezava med starostjo bolnikov in slikovnimi ali histološkimi ugotovitvami ni bila statistično značilna. Zaključki. Povezava med mamografskim izgledom mikrokalcinacij in histološkim rezultatom, ki jo pogosteje najdemo pri bolj agresivni bolezni, je lahko v pomoč pri optimalnem načrtovanju kirurgije pri bolnicah z netipnim duktalnim rakom in situ in sicer pri obsegu operacije in možnosti istočasne odstranitve varovalne bezgavke. RadiolOncol 2016; 50(2): 153-158. doi:10.1515/raon-2016-0022 Privzem 18F-FET in 18F-FCH v celicah humanega glioblastoma T98G Persico MG, Buroni FE, Pasi F, Lodola L, Aprile C, Nano R, Hodolič M Izhodišča. Kljub zdravljenju s kombinacijo operacije, obsevanja in kemoterapije se gliomi visoke stopnje malignosti pogosto ponovijo. Razlikovanje med spremembami po zdravljenju in ponovitvijo bolezni je težko. 18F-metil-holin (18F-FCH) pogosto uporabljamo za odkrivanje in določanje stadija bolezni pri ponavljajočih rakih prostate, kot tudi nekaterih možganskih tumor­jih; vendar količina vnetja zmanjšuje specifičnost te preiskovalne metode. Maligne celice možganskih tumorjev pa, verjetno zaradi povečanega izražanja prenašalcev aminokislin ali zaradi prehajanja preko možgansko-krvne bariere, specifično privze­majo 18F-etil-tirozin (18F-FET). 18F-FET se slabše izraža v makrofagih in drugih vnetnih celicah. Cilj naše raziskave je bil primerjati privzem 18F-FCH in 18F-FET v celični liniji humanega glioblastoma T98G. Material in metode. Celicam humanega glioblastoma T98G in kožnim fibroblastomom gostote 2 x 105, ki so rasle pritrje­ne na dnu gojitvene posode ob 37 °C in 5% CO2 smo dodali ekvimolarno količino radioaktivnnih označevalcev 18F-FCH oz. 18F-FET in jih nato gojili od 20 do 120 minut. Količino privzetega radioaktivnega označevalca v celicah smo določili s števcem gama. Vse poskuse smo izvedli v dvojniku in jih ponovili trikrat. Rezultate privzema radioaktivnega označevalca smo izrazili kot odstotek doze označevalca na 2 x 105 celic. Rezultate izražene kot povprečne vrednosti v odstotkih privzema smo analizirali z uporabo parametričnih ali neparametričnih testov, za značilne so veljale vrednosti p < 0,05. Rezultati. Rezultati so pokazali statistično značilne razlike v privzemu 18F-FCH v celicah T98G po 60, 90 in 120 minutah. Privzem 18F-FET je bil v primerjavi s privzemom 18F-FCH ob različni farmakokinetični krivulji nižji za več kot trikrat. Privzem 18F-FET je pokazal hitrejši začetni privzem z največjimi vrednostmi do 40 minut, medtem ko je bil pri 18F-FCH viden postopen dvig z najvišjimi vrednostmi po 90 minutah. Zaključki. 18F-FCH in 18F-FET sta primerna za nevroonkološko slikanje PET. Uporabnost 18F-FET kot onkološkega označevalca PET je zlasti velika ob prisotnosti sprememb po zdravljenju, saj je zaradi večje afinitete vnetnih celic za 18F-FCH težko razlikovati med ostanki tumorja in nerakastimi spremembami. Potrebne so dodatne raziskave o vplivu vnetnih tkiv in nekroze na radio­farmakološki privzem obeh označevalcev. Radiol Oncol 2016; 50(2): 159-167. doi:10.1515/raon-2016-0017 Vizualizacija celic človeškega glioblastoma in njihovih interakcij z mezenhimskimi matičnimi celicami v možganih zarodkov cebric (Danio rerio) Vittori M, Breznik B, Gredar T, Hrovat K, Bizjak Mali L, Lah TT Izhodišča. Novo zanimivo proučevanje raka pri človeku je uporaba prosojnih zarodkov rib cebric, ki omogoča opazovanje napredovanja raka v živih živalih. Materiali in metode. Mešanice fluorescentno označenih celic glioblastoma in mezenhimskih matičnih celic smo vsadili v zarodke rib cebric, da bi preučevali njihove poti celične invazije in interakcije med tema dvema vrstama celic in vivo. Rezultati. Razvili smo protokol bistrenja tkiv, ki je kompatibilen z uporabo karbocianinskih barvil, ker je omogočil mikroskopijo fluorescentno označenih celic globoko v tkivih. Na ta način smo pokazali, da sta tako glioblastomska celična linija U87 kot tudi U373 hitro agregirali v tumorsko maso v ventriklih in hemisferah srednjih možganov, od koder sta se širili predvsem preko ventriklov in osrednjega kanala hrbtenjače, vendar pri tem celice glioblastoma niso zapustile osrednjega živčevja. Ko smo v možgane vnesli različno označene glioblastomske celice skupaj z mezenhimskimi matičnimi celicami, so se v možganih rib oblikovali mešani tumorji. Med glioblastomskimi celicami in mezenhimskimi matičnimi celicami smo opazili tesne povezave in tudi fuzije različnih vrst celic. Glioblastomske celice in mezenhimske matične celice so v osrednje živčevje invadirale po podobnih poteh. Zaključki. Ta preprost model lahko uporabimo za preučevanje molekulskih poti v celičnih procesih pri invaziji glioblastom­skoh celic in njihovih interakcijah z različnimi celicami strome v dvojnih ali trojnih sokulturah. To lahko vodi k razvoju novih celičnih terapij glioblastoma z uporabo mezenhimskih matičnih celic kot celičnih vektorjev. Radiol Oncol 2016; 50(2): 168-174. doi:10.1515/raon-2016-0010 Identifikacija diferencialno izraženih genov povezanih s povečanjem občutljivosti na rentgenske žarke z RITA na celični liniji ploščatoceličnega raka ustnega žrela (FaDu) Luan J, Li X, Guo R, Liu S, Luo H, You Q Izhodišča. Za raziskovanje mehanizma reaktivacije p53 in indukcije apoptoze tumorskih celic (RITA), ki poveča občutljivost celic FaDu na rentgenske žarke, smo uporabili sekvenciranje nove generacije in bioinformatsko analizo. Materiali in metode. Molekule cDNA smo izolirali iz celic FaDu, ki smo jih izpostavili obsevanju z 0 Gy, 8 Gy ali 8 Gy + RITA. Nato smo pripravili cDNA knjižnice in jih sekvencirali s sekvenciranjem nove generacije. Poskus smo ponovili dvakrat. Nato smo ugotavljali diferencialno izražene gene (DEG) s pomočjo algoritma Cuffdiff v Cufflinks in njihove funkcije napovedali z oboga­titveno analizo različnih poti. Gene, ki so bili stalno povečano ali zmanjšano izraženi pri celicah FaDu, izpostavljenih obsevanju z 8 Gy ali 8 Gy + RITA, smo vzeli za gene RITA. Nato smo določili interakcije protein-protein (PPI) z bazo podatkov STRING in zgra­dili njihovo mrežo s Cytoscape programom. Za obogatitveno analizo za gene v mreži PPI smo uporabili algoritem ClueGO. Rezultati. V celicah FaDu izpostavljenih obsevanju z 8 Gy smo ugotovili 2040 DEG, v celicah FaDu izpostavljenih obsevanju z 8 Gy + RITA pa 297. Pri popravljanju z izrezovanjem baz sta bil najbolj obogatena gena PARP3 in NEIL1, pri signalni poti p53 pa smo CDK1, RFC2 in EZH2 prepoznali kot gene RITA. V mreži PPI smo ugotovili več interakcij med proteini (RFC2-CDK1, EZH2­CDK1 in PARP3-EZH2). Z analizo ClueGO smo pokazali, da sta RFC2 in EZH2 povezana s celičnim ciklom. Zaključki. RFC2, EZH2, CDK1, PARP3 in NEIL1 so verjetno med seboj povezani in skupaj povečajo občutljivost celic FaDu, ki smo ji izpostavili RITA, na škodljive vplive rentgenskih žarkov. Radiol Oncol 2016; 50(2): 175-187. doi:10.1515/raon-2016-0018 Magnetnoresonančna mikroskopija difuzijskega tenzorja tkiv z nizko difuzijsko anizotropijo Bajd F, Mattea C, Stapf S, Serša I Izhodišča. Magnetnoresonančno slikanje difuzijskega tenzorja izkorišča preferenčne smeri difuzijskega gibanja vodnih molekul v opazovanem tkivu za oceno stopnje strukturne anizotropije tkiva. Vendar je izračun difuzijskega tenzorja močno obremenjen z mersko napako, ki ima izvor v instrumentalnem šumu. V raziskavi smo analizirali številne dejavnike, ki vplivajo na točnost izračuna difuzijskega tenzorja. Materiali in metode. Proučili smo učinke razmerja signal-šum in konfiguracije uporabljenih difuzijskih gradientov na točnost določitve frakcijske anizotropije z uporabo numeričnih simulacij. Rezultate simulacije smo preverili tudi z magnetno­resonančno mikroskopijo difuzijskega tenzorja izotropnega vodnega vzorca in strukturno neizotropnega vzorca govejega sklepnega hrustanca ex vivo. Rezultati. Tako v rezultatih simulacije kot tudi v poskusih smo s pomočjo uporabe multivariatne linearne regresije dobili precenjene vrednosti frakcijske anizotropije za majhne vrednosti razmerja med signalom in šumom ter pri majhnem številu smeri difuzijskih gradientov. Zaključki. Povečanje frakcijske anizotropije zaradi neugodnih eksperimentalnih pogojev je mogoče zmanjšati z uporabo večjega števila smeri difuzijskih gradientov, kakor tudi z zmanjšanjem pogojnega števila difuzijske transformacijske matrike. To je zlasti pomembno pri magnetnoresonančni mikroskopiji, kjer uporabljamo močne slikovne gradiente in je razmerje med signalom in šumom običajno nizko. Radiol Oncol 2016; 50(2): 188-196. doi:10.1515/raon-2015-0027 Prognostična vloga izražanja mRNA SOX2, NANOG in OCT4 v celotni krvi pri napredovalem drobnoceličnem pljučnem raku Sodja E, Rijavec M, Koren A, Sadikov A, Korošec P, Čufer T Izhodišča. Izražanje in klinični vpliv označevalcev rakavih matičnih celic SOX2, NANOG in OCT4 pri pljučnem raku še vedno nista znana. Namen raziskave je bil primerjati ravni izražanja mRNA SOX2, NANOG in OCT4 v celotni krvi med bolniki z napre­dovalim drobnoceličnim pljučnim rakom in zdravimi posamezniki ter povezati njihovo izražanje s preživetjem brez napredo­vanja bolezni po prvem redu kemoterapije in s celokupnim preživetjem pri bolnikih z napredovalo obliko drobnoceličnega pljučnega raka. Bolniki in metode. Prospektivno smo vključili 50 bolnikov z napredovalim drobnoceličnim pljučnim rakom, ki smo jih v letih med 2009 in 2013 zdravili s kemoterapijo v Univerzitetni bolnišnici Golnik. Raven izražanja SOX2, NANOG in OCT4 smo določili s kvantitativnim testom RT-PCR in tehnologijo TaqMan v vzorcih celotne krvi, odvzetih pred začetkom zdravljenja. Za primerjavo smo testirali tudi vzorce celokupne krvi 34 zdravih posameznikov. Rezultati. Raven izražanja SOX2 je bila statistično značilno višja v celotni krvi bolnikov z drobnoceličnim pljučnim rakom v primerjavi z zdravimi posamezniki (p = 0,006). Prav tako smo opazili statistično značilno povezavo med izražanjem SOX2 in številom oddaljenih metastatskih mest (p = 0,027). Bolniki s povišano ravnjo izražanja SOX2 so imeli krajše celokupno preživetje (p = 0,017) in krajše preživetje brez napredovanja bolezni (p = 0,046). V multivariatni analizi Cox smo potrdili neodvisno vlogo izražanja SOX2 za celokupno preživetje (p = 0,002). V primerjavi ravni izražanja NANOG in OCT4 med bolniki z drobnoceličnim pljučnim rakom in zdravimi posamezniki nismo opazili statistično značilnih razlik, prav tako za oba omenjena označevalca nismo opazili statistično pomembnih povezav v analizi preživetja bolnikov z drobnoceličnim pljučnim rakom. Zaključki. Izražanje SOX2 v celotni krvi je obetaven neinvaziven označevalec za molekularno presejanje drobnoceličnega pljučnega raka in pomemben napovedni označevalec pri bolnikih z napredovalim drobnoceličnim pljučnim rakom zdravlje­nih s kemoterapijo, kar nakazuje pomembno vlogo regulatorjev rakavih matičnih celic pri širjenju raka. Potrebne so dodatne raziskave, ki bi ovrednotile izražanje SOX2 kot potencialnega presejalnega/napovednega označevalca in terapevtsko tarčo pri drobnoceličnem pljučnem raku. Radiol Oncol 2016; 50(2): 197-203. doi:10.1515/raon-2016-0002 Vstavljanje Tenckhoffovega tunelskega peritonealnega katetra pri paliativnem zdravljenju malignega ascitesa. Tehnični rezultati in skupni klinični izid Maleux G, Indesteege I, Laenen A, Verslype C, Vergote I, Prenen H Izhodišča. Namen raziskave je bil ovrednotiti tehnični in klinični izid perkutanega vstavljanja tunelskega peritonealnega ka­tetra pri paliativnem zdravljenju neodzivnega malignega ascitesa ter določiti varnost in izvedljivost intraperitonealne uporabe citostatikov skozi tunelski kateter. Bolniki in metode. V raziskavo smo vključili zaporedno zdravljene bolnice, ki smo jim s tunelskim peritonealnim katetrom drenirali maligni ascites. Podatke o zdravljenju, klinično sledenje, vključno z zapleti in predvidenim preživetjem smo ugotavljali pri vsaki bolnici. Poleg tega smo opravili analizo pri tistih bolnicah, ki so imele razširjeni rak jajčnikov in smo jih ali pa ne zdravili z intraperitonelano aplikacijo citostatikov. Rezultati. Pri vseh 94 bolnicah je bilo tehnično možno izvesti vstavitev peritonealnega katetra in skozi kateter se je izločilo 3260 cm3 srednje vrednosti (razpon 100–850 cm3) malignega ascitesa. Zapleti po postopku so predstavljali infekcijo katetra (n = 2; 2 %), uhajanje tekočine okoli mesta vstavitve (n = 4; 4 %), zaporo katetra (n = 2; 2 %), nastanek rokava okoli konice katetra (n = 1; 1 %) in nenamerno izgubo katetra (n = 1; 1 %). Pri bolnicah, ki so bile ali pa ne zdravljene z intraperitonealno aplikacijo citostatikov ni bilo povečanega tveganja za infekcijo katetra. Srednja vrednost celokupnega preživetja po vstavitvi katetra je bila 1,7 meseca. Zaključki. Perkutano vstavljanje Tenckhoffovega tunelskega katetra za paliativno odstranjevanje malignega ascitesa in intraperitonealna infuzija citostatikov je izvedljiva metoda, ki je povezana z zelo nizko stopnjo zapletov, vključno z infekcijami katetra. Tunelski katetri so koristni pri simptomatskem paliativnem zdravljenju neodzivnih ascitesov in omogočajo varno intra­peritonealno kemoterapijo. Radiol Oncol 2016; 50(2): 204-211. doi:10.1515/raon-2015-0025 Serumski nivo CA19-9 napoveduje mikrometastaze pri bolnikih z rakom želodca Jagrič T, Potrč S, Miš K, Plankl M, Marš T Izhodišča. Namen raziskave je bil ugotoviti, ali lahko povišan nivo karbohidratnega antigena 19-9 (CA19-9) napoveduje mikrometastaze pri bolnikih z želodčnim rakom in negativnimi bezgavkami. Bolniki in metode. Mikrometastaze smo določili s kvantitativno reverzno transkripcijsko polimerazno verižno reakcijo (RT­qPCR) pri 30 bolnikih z želodčnim rakom in negativnimi bezgavkami. Skupina je določala mejne vrednosti predoperativnega serumskega nivoja antigena CA19-9 kot nadomestnega pokazatelja za mikrometastaze. Nato smo pri 187 bolnikih z želodč­nim rakom stadija T1 do T4 in N0 preverili napovedno vrednost antigena CA19-9 za mikrometastaze. Rezultati. Bolniki z mikrometastazami so imeli značilno višje predoperativne vrednosti CA19-9 v serumu v primerjavi z bolniki brez mikrometastaz (p = 0,046). Serumski nivo CA19-9 je bil soodvisen z lokacijo tumorja, njegovim premerom in perinevralno invazijo. Čeprav razlika ni bila statistično značilna, je bilo petletno preživetje bolnikov s serumskimi vrednostmi CA19-9 pod mej­no vrednostjo boljše v primerjavi z bolniki, ki so imeli vrednosti CA19-9 nad mejno vrednostjo. Kumulativno preživetje bolnikov stadija T2 do T4 in N0 je bilo značilno boljše pri tistih bolnikih, ki so imeli serumske vrednosti CA19-9 pod mejnimi vrednostmi (p = 0,04). Zaključki. Predoperativni serumski nivo CA19-9 kaže na visoko tveganje za nastanek hematogene razširitve in mikrometa­staz pri bolnikih z želodčnim karcinomom z negativnimi bezgavkami. Vendar pa ugotavljanje serumskega nivoja CA19-9 nima dovolj visoke občutljivosti in specifičnosti, da bi zanesljivo napovedoval mikrometastaze. Radiol Oncol 2016; 50(2): 212-217. doi:10.2478/raon-2014-0040 Jetrna splenoza pri bolniku z anamnezo nezrelega teratoma v otroštvu, ki na videz posnema jetrne zasevke Jereb S, Trotovšek B, Škrbinc B Izhodišča. Jetrna splenoza je prisotnost vsadkov normalnega vraničnega tkiva v jetrnem parenhimu. Je redka in nastane po splenektomiji ali poškodbi vranice. Predvsem pri bolnikih z anamnezo malignega obolenja jo lahko zmotno ocenimo kot zasevke, kar vodi v nepotrebne diagnostične postopke in neustrezno zdravljenje. Prikaz primera. 22-letnega bolnika so po rojstvu operativno zdravili zaradi nezrelega teratoma, povezanega z nespu­ščenim desnim testisom. Na rednih kontrolnih pregledih onkologi niso ugotavljali ponovitve bolezni ali dolgotrajnih posledic. Zaradi suma na levostransko dimeljsko kilo so naredili elektivni operativni poseg, tvorbo v kilni vreči pa so histološko opredelili kot policističen zrel teratom. Ocenili so, da so odstranili zasevek teratoma iz otroštva. Origo bolezni v preostalem, levem testisu niso našli. Slikovne diagnostične metode, opravljene v nadaljevanju, so pokazale prisotnost jetrnih sprememb, ki so bile radio­loško sumljive za zasevke. Naredili so dve ultrazvočno vodeni tankoigelni aspiracijski biopsiji omenjenih sprememb, ki nista bili diagnostični. Laparoskopsko pridobljen histološki vzorec sumljivega tkiva je pokazal normalno vranično tkivo. Tako so potrdili diagnozo jetrne splenoze. Zaključki. Kljub temu, da je jetrna splenoza redek pojav, jo moramo vključiti med diferencialne diagnoze nodularnih jetrnih sprememb. Njihova natančna opredelitev je ključnega pomena za ustrezno obravnavo bolnika. Če citološka punkcija ne da ustreznega odgovora, je pred obsežnejšo jetrno resekcijo laparoskopska ekscizija nodularne spremembe najboljša rešitev. Radiol Oncol 2016; 50(2): 218-225. doi:10.1515/raon-2016-0001 Zdravljenje raka nosnega žrela s sočasnim moduliranim in pospešenim obsevanjem s helično tomoterapijo. Raziskava II. faze Du L, Zhang XX, Feng LC, Chen J, Yang J, Liu HX, Xu SP, Xie CB, Ma L Izhodišča. Namen raziskave je bil oceniti kratkoročno varnost in učinkovitost sočasnega moduliranega in pospešenega obsevanja (SMART) s helično tomoterapijo pri bolnikih z rakom nosnega žrela. Metode. V prospektivno raziskavo II. faze smo med avgustom 2011 in septembrom 2013 vključili 132 novoodkritih bolnikov z rakom nosnega žrela. Predpisane doze na volumen primarnega tumorja (pGTVnx) in prizadete bezgavke (pGTVnd), na planirni tarčni volumen visokega tveganja (PTV1) in planirni tarčni volumen nizkega tveganja (PTV2) so bile 67,5 Gy (2,25 Gy/frakcijo), 60 Gy (2,0 Gy/frakcijo) in 54 Gy (1,8 Gy/frakcijo). Akutne neželene učinke smo ocenili z uveljavljenimi kriteriji RTOG/EORTC. To skupino bolnikov smo primerjali z 190 bolniki iz retrospektivne raziskave P70, ki smo jih zdravili med septembrom 2004 in avgu­stom 2009 s helično tomoterapijo in dozo na pGTVnx in pGTVnd 70–74 Gy/33 frakcij/v 6,5 tednih. Rezultati. Srednji čas spremljanja je bil 23,7 (12–38) mesecev. Akutni, z obsevanjem povezani stranski učinki so bili poglavi­tna težava in smo jih ocenili s stopnjo 1 ali 2. Le manjše število bolnikov je imelo levkopenijo (4,5 %) ali trombocitopenijo (2,3 %) stopnje 4. Preživetje brez lokalne ponovitve (LRFS), preživetje brez področne ponovitve (NRFS), preživetje brez lokalne in področne ponovitve (LNRFS), preživetje brez oddaljenih zasevkov (DMFS) in celokupno preživetje (OS) je bilo po dveh letih sledenja 96,7 %, 95,5 %, 92,2 %, 92,7 % in 93,2 % ter brez pomembnih razlik glede na raziskavo P70. Zaključki. Dosedanji rezultati kažejo, da ima pri bolnikih z rakom nosnega žrela SMART s helično tomoterapevtsko tehniko sprejemljivo akutno toksičnost in ugoden kratkoročen izid zdravljenja. Kasno toksičnost in preživetje bolnikov še ugotavljamo. Radiol Oncol 2016; 50(2): 226-231. doi:10.1515/raon-2015-0030 Bevacizumab s kemoterapijo pri starejših bolnikih s predhodno nezdravljenim metastatskim rakom debelega črevesa in danke. Izkušnje posamičnega centra Ocvirk J, Maja Ebert Moltara M, Mesti T, Boc M, Reberšek M, Volk N, Benedik J, Hlebanja Z Izhodišča. Metastatski rak debelega črevesa in danke je predvsem bolezen starejših. Geriatrična populacija pa je pre­malo zastopana v kliničnih raziskavah. Registri bolnikov predstavljajo orodje za ocenjevanje in sledenje rezultatov zdravljenja tudi pri tej populaciji bolnikov. Namen raziskave je bil s pomočjo registra bolnikov ugotoviti varnost in učinkovitost zdravljenja z bevacizumabom in kemoterapijo pri starejših bolnikih, ki so imeli predhodno nezdravljen rak debelega črevesa in danke. Bolniki in metode. Register bolnikov z metastatskim rakom debelega črevesa in danke smo zasnovali zaradi prospektiv­nega ocenjevanja varnosti in učinkovitosti kemoterapije in bevacizumaba. Z njim smo tudi ugotavljali izbor bolnikov za takšno zdravljenje v vsakodnevni klinični praksi. Zbirali in ovrednotili smo osnovne klinične značilnosti bolnikov, vnaprej opredeljene neželene dogodke, povezane z bevacizumabom, in podatke o učinkovitosti zdravljenja ter naredili primerjavo glede na starostne kategorije. Rezultati. Od januarja 2008 do decembra 2010 smo 210 bolnikov z metastatskim rakom debelega črevesa in danke (srednja starost 63, moški 61,4 %) začeli zdraviti z bevacizumabom. To je bilo njihovo prvo zdravljenje. Večina bolnikov je prejela ob bevacizumabu kemoterapijo prvega reda, ki je temeljila na irinotekanu (68 %), 105 bolnikov (50 %) pa je prejelo vzdrževalno zdravljenje z bevacizumabom. Starejših (. 70 let) bolnikov je bilo 22,9 % in so imeli slabše stanje zmogljivosti (PS 1–2 v 62,4%) kot bolniki v skupini <70 let (PS 1–2 v 35,8 %). Ugotovili smo razliko v deležu nadzora bolezni, ki smo jo pripisali nezmožnosti ocenitve odziva na zdravljenje pri skupini starejših bolnikov (64,6 % pri starejših in 77,8 % v skupini < 70 let, p = 0,066). Srednje preživetje brez napredovanja bolezni je bilo 10,2 (95% interval zaupanja [CI] 6,7–16,2) mesecev pri starejših in 11,3 (95% CI 10,2–12,6) v skupini < 70 let (p = 0,58). Srednje celokupno preživetje je bilo 18,5 (95% CI 12,4–28,9) mesecev za starejše in 27,4 (95% CI 22,7–31,9) za skupino < 70 let (p = 0,03). Triletno preživetje je bilo 26 % pri starejših in 37,6 % pri skupini < 70 let (p = 0,03). Stopnje neželenih učinkov, povezanih z bevacizumabom je bila v obeh skupinah podobna: proteinurija 21 % pri starejših vs. 22 % pri skupini < 70 let, hipertenzija 25 vs. 19 %, krvavitev 2 vs. 4% in trombembolični dogodki 10 vs 6%. Zaključki. Kombinacija bevacizumaba in kemoterapije, ki jo uporabljamo v vsakodnevni klinični praksi, je učinkovita in jo starejši bolnikih z metastatskim rakom debelega črevesa in danke dobro prenašajo. Radiol Oncol 2016; 50(2): 232-237. doi:10.1515/raon-2016-0012 Dozimetrični pomen uporabe fotonov 10 MV pri obsevanju prostatične lože po prostatektomiji z volumetrično modulirano ločno terapijo (VMAT) Kleiner H, Podgorsak M Izhodišča. Namen raziskave je bil analiza dozimetričnih razlik ob uporabi 10 MV namesto 6 MV obsevalnih načrtov VMAT pri obsevanju prostatične lože po prostatektomiji. Metode. Pri desetih primerih obsevanja prostatične lože po prostatektomiji, ki smo jih predhodno že zdravili s 6 MV VMAT, smo ponovno naredili obsevalni načrti za obsevanje z 10 MV VMAT. Predpisana doza je bila 66,6 Gy, razdeljena v 37 dnevnih odmerkov po 1,8 Gy. Za načrtovanje s 6 MV in 10 MV smo uporabili enak nabor struktur, število lokov, velikost polj in minimalno dozo na planirni tarčni volumen (PTV). Zbrali smo dozimetrične rezultate za rizične organe, doze na tarčne strukture, število mo­nitorskih enot za vsak lok, odstotek volumna, ki je prejel 5 Gy (Body V5), konformnostni indeks in integralno dozo. Za primerjavo rezultatov obsevanja 6 MV in 10 MV smo uporabili povprečne vrednosti. Za ugotavljanje statističnega pomena rezultatov pa smo uporabili parni Studentov t test. Rezultati. Statistično pomembno nižje povprečne vrednosti smo ugotovili za rizične organe: danko, klinični tarčni volumen, ki je zajemal mehur, levo glavico stegnenice in desno glavico stegnenice. Statistično pomembno nižje povprečne vrednosti smo ugotovili tudi za Body V5, konformnostni indeks in integralno dozo. Zaključki. Pri uporabi obsevalnih načrtov VMAT 10 MV namesto 6 MV smo ugotovili več dozimetričnih prednosti. Te so vklju­čevale obvarovanje rizičnih organov pred višjo dozo, pri čemer smo ohranili dozo na PTV. Ostale prednosti so se nanašale na Body V5, konformnostni indeks in integralno dozo. Radiol Oncol 2016; 50(2): 238-246. doi:10.1515/raon-2016-0019 Vpliv spektra fotonskih energij na dozimetrične lastnosti brahiterapevtskih virov Ghorbani M, Mohammad M, David D, Ahmadi Moghaddas T Izhodišča. Namen raziskave je bil kvantitativno opredeliti vpliv fotonskega energijskega spektra brahiterapevtskih virov na parametre dozimetričnega sistema TG-43. Za posamezne radionuklide v simulacijah Monte Carlo namreč uporabljamo različne fotonske energijske spektre. Materiali in metode. Za numerično simulacijo brahiterapevtskih virov 125I, 103Pd, 169Yb in 192Ir smo uporabili kodo MCNPX. Tako smo izračunali: moč vira glede na aktivnost, konstanto hitrosti doze, funkcijo radialne doze in dvodimenzionalno (2D) anizotropijsko funkcijo. Izodozne krivulje smo izrisali za tri različne fotonske energijske spektre. Pri izračunu spektrov fotonskih energij smo upoštevali: objavljene članke, Nacionalni laboratorij Lawrence Berkeley (NBNL) in Nacionalni center za nuklearne podatke (NNDC). Podatke, ki smo jih izračunali s pomočjo teh spektrov fotonskih energij smo primerjali med seboj. Rezultati. Največja razlika med vrednostmi konstant hitrosti doze je bila 24,07 % pri viru 103Pd z različnimi spektri fotonskih energij. Vrednosti funkcije radialne doze so bile dokaj podobne po različnih spektrih. Vrednosti funkcije 2D anizotropije so po­kazale le majhne razlike pri večini razdalj in kotov. Med izodoznimi krivuljami nismo ugotovili nobene opazne razlike. Zaključki. Dozimetrični parametri, dobljeni z različnimi fotonskimi spektri, so si podobni. Vseeno priporočamo za simulacije Monte Carlo uporabo bolj natančnih in posodobljenih spektrov fotonskih energij. To bi omogočilo zanesljivejše dozimetrične podatke pri modeliranjih virov in izračunavanjih v brahiterapevtskih načrtovalnih sistemih. Fundacija "Docent dr. J. Cholewa" je neprofitno, neinstitucionalno in nestrankarsko združenje posameznikov, ustanov in organizacij, ki želijo materialno spodbujati in poglabljati raziskovalno in izobraževalno dejavnost v onkologiji. Fundacija »docent dr. Josip Cholewa« v sodelovanju z Medicinsko fakulteto Ljubljana, Medicinsko fakulteto Maribor, Univerzitetnim kliničnim centrom Ljubljana, Univerzitetnim kliničnim centrom Maribor in Onkološkim Inštitutom Ljubljana PRIREJA STROKOVNI SIMPOZIJ Z NASLOVOM: DIAGNOSTIKA IN ZDRAVLJENJE ZGODNJEGA RAKA Simpozij bo potekal v Ljubljani, dne 7. oktobra 2016 v Modri dvorani Domus Medica, Dunajska cesta 162. Dunajska 106 1000 Ljubljana TRR: 02033-0017879431 Uporabljena moška slovnična oblika se enakovredno nanaša na oba spola. Activity of "Dr. J. Cholewa" Foundation for Cancer Research and Education – a report for the second quarter of 2016 Dr. Josip Cholewa Foundation for cancer research and education continues with its planned activities in the second quarter of 2016. Its primary focus remains the provision of grants and scholarships and other forms of financial assistance for basic, clinical and public health research in the field of oncology. In parallel, it also makes efforts to provide financial and other support for the organisation of congresses, symposia and other forms of meetings to spread the knowledge about prevention and treatment of cancer, and finally about rehabilitation for cancer patients. In Foundation's strategy the spread of knowledge should not be restricted only to the professionals that treat cancer patients, but also to the patients themselves and to the general public. The Foundation continues to provide support for »Radiology and Oncology«, a quarterly scientific maga­zine with a long tradition and with a respectable impact factor that publishes research and review articles about all aspects of cancer. The magazine is edited and published in Slovenia. The Foundation will continue with its activities in the future, especially since the problems associated with cancer affect more and more people in Slovenia and elsewhere. Ever more successful treatment results in longer survival in many patients with previously incurable cancer conditions, thus adding many new di­mensions in life of cancer survivors and their families. Borut Štabuc, M.D., Ph.D. Tomaž Benulič, M.D. Andrej Plesničar, M.D., M.Sc. Viljem Kovač M.D., Ph.D. SLHR-SL-P-003-0416-129220 NEULASTA® 6 mg raztopina za injiciranje (pegfilgrastim) – SKRAJŠAN POVZETEK GLAVNIH ZNAČILNOSTI ZDRAVILA Samo za strokovno javnost. Pred predpisovanjem si preberite celoten Povzetek glavnih značilnosti zdravila. SESTAVA ZDRAVILA: Ena napolnjena injekcijska brizga vsebuje 6 mg pegfilgrastima v 0,6 ml (10 mg/ml) raztopine za injiciranje. TERAPEVTSKE INDIKACIJE: Skrajšanje trajanja nevtropenije in zmanjšanje incidence febrilne nevtropenije pri odraslih bolnikih, zdravljenih s citotoksično kemoterapijo za maligne bolezni (z izjemo kronične mieloidne levkemije in mielodisplastičnih sindromov). ODMERJANJE IN NAČIN UPORABE: Zdravljenje z zdravilom Neulasta® morajo uvesti in nadzorovati zdravniki, izkušeni v onkologiji in/ali hematologiji. Za vsak cikel kemoterapije priporočajo en 6 mg odmerek (eno napolnjeno injekcijsko brizgo) zdravila Neulasta®, ki je dana vsaj 24 ur po citotoksični kemoterapiji. Zdravilo Neulasta® se injicira subkutano. Injekcije se morajo dati v stegno, trebuh ali zgornji del roke. Varnost in učinkovitost zdravila Neulasta® pri otrocih še nista bili dokazani in priporočil o odmerjanju ni mogoče dati. Pri bolnikih z okvaro ledvic in s končno odpovedjo ledvic odmerka ni treba spreminjati. KONTRAINDIKACIJE: Preobčutljivost za zdravilno učinkovino ali katerokoli pomožno snov. POSEBNA OPOZORILA IN PREVIDNOSTNI UKREPI: Pri bolnikih z de novo akutno mieloično levkemijo omejeni klinični podatki kažejo primerljiv učinek pegfilgrastima in filgrastima na čas do okrevanja po hudi nevtropeniji. Dolgoročni učinki zdravila Neulasta® pri akutni mieloični levkemiji niso ugotovljeni, zato ga je treba pri tej populaciji bolnikov uporabljati previdno. Varnost in učinkovitost zdravila Neulasta® nista raziskani pri bolnikih z mielodisplastičnim sindromom, s kronično mielogeno levkemijo in s sekundarno akutno mieloično levkemijo (AML), zato ga pri takšnih bolnikih ne smete uporabljati. Posebno pozornost je treba nameniti razlikovanju diagnoze blastne transformacije kronične mieloične levkemije od akutne mieloične levkemije. Varnost in učinkovitost uporabe zdravila Neulasta® pri bolnikih z de novo AML, mlajših od 55 let in s citogenetiko t(15;17), nista ugotovljeni. Varnosti in učinkovitosti zdravila Neulasta® niso raziskovali pri bolnikih, ki prejemajo kemoterapijo v velikih odmerkih. Tega zdravila ne smete uporabljati za zvečevanje odmerka citotoksične kemoterapije preko uveljavljenih shem odmerjanja. Neželene reakcije na pljučih: Bolj ogroženi so lahko bolniki z nedavno anamnezo pljučnih infiltratov ali pljučnice. Pojav pljučnih znakov, kot so kašelj, zvišana telesna temperatura in dispneja v povezavi z radiološkimi znaki pljučnih infiltratov, in poslabšanje pljučne funkcije skupaj z zvečanim številom nevtrofilcev utegnejo biti preliminarni znaki sindroma akutne dihalne stiske (ARDS -'Acute Respiratory Distress Syndrome'). V takih primerih je treba zdravilo Neulasta® po presoji zdravnika prenehati dajati in poskrbeti za ustrezno zdravljenje. Glomerulonefritis: Na splošno so primeri glomerulonefritisa minili po zmanjšanju odmerka ali prenehanju uporabe filgrastima ali pegfilgrastima. Priporočljivo je spremljanje laboratorijskih izvidov urina. Sindrom kapilarne prepustnosti: Bolnike, ki se jim pojavijo simptomi sindroma kapilarne prepustnosti, je treba natančno kontrolirati in deležni morajo biti standardnega simptomatskega zdravljenja, ki lahko vključuje potrebo po intenzivni negi. Splenomegalija in ruptura vranice: Skrbno je treba spremljati velikost vranice (s kliničnim pregledom, ultrazvokom). Na diagnozo rupture vranice moramo misliti pri bolnikih, ki poročajo o bolečini v zgornjem levem delu trebuha ali v predelu lopatice. Trombocitopenija in anemija: Zdravljenje s samim zdravilom Neulasta® ne prepreči trombocitopenije in anemije, ker se hkrati vzdržuje mielosupresivna kemoterapija s polnimi odmerki po predpisani shemi. Priporočajo redno spremljanje števila trombocitov in hematokrita. Posebna previdnost je potrebna med uporabo posameznih kemoterapevtikov ali njihovih kombinacij, za katere je znano, da povzročajo hudo trombocitopenijo. Srpastocelična anemija: Pri bolnikih s srpastocelično dispozicijo ali s srpastocelično anemijo je bila uporaba pegfilgrastima povezana s srpastocelično krizo, zato se mora pri teh bolnikih zdravilo Neulasta® predpisovati previdno in spremljati ustrezne klinične parametre in laboratorijski status in biti pozoren na morebitno povezavo tega zdravila z zvečanjem vranice in vazookluzivno krizo. Levkocitoza: Zaradi kliničnih učinkov zdravila Neulasta® in zaradi možnosti levkocitoze je treba med zdravljenjem redno kontrolirati število belih krvničk. Če število levkocitov po pričakovanem najmanjšem številu preseže 50 x 109/l, je treba nemudoma prenehati z zdravljenjem s tem zdravilom. Preobčutljivost: Dokončno prenehajte z zdravljenjem z zdravilom Neulasta® pri bolnikih s klinično signifikantno preobčutljivostjo. Zdravila Neulasta® ne dajajte bolnikom z anamnezo preobčutljivosti na pegfilgrastim ali filgrastim. V primeru resne alergijske reakcije je treba poskrbeti za ustrezno zdravljenje in pazljivo spremljanje bolnika še nekaj dni. Imunogenost: Kot pri vseh terapevtskih beljakovinah obstaja možnost imunogenosti. Stopnja nastajanja protiteles proti pegfilgrastimu je na splošno nizka. Vezavna protitelesa se pojavijo po pričakovanjih pri vseh bioloških zdravilih, vendar jih doslej niso povezali z nevtralizacijskim delovanjem. Varnosti in učinkovitosti zdravila Neulasta® za mobilizacijo matičnih krvotvornih celic pri bolnikih ali zdravih dajalcih niso primerno ovrednotili. Pokrovček igle pri napolnjeni injekcijski brizgi vsebuje suho naravno gumo (derivat lateksa), ki lahko povzroča alergične reakcije. Povečana hemopoetična aktivnost kostnega mozga zaradi zdravljenja z rastnimi dejavniki je bila povezana s prehodnimi pozitivnimi izvidi pri slikanju kosti, kar je treba upoštevati pri interpretaciji iz vidov na podlagi slikanja kosti. Zdravilo Neulasta® vsebuje sorbitol. Bolniki z redko prirojeno motnjo intolerance za fruktozo ne smejo dobiti tega zdravila. Zdravilo Neulasta® vsebuje manj kot 1 mmol (23 mg) natrija na 6 mg odmerek, kar v bistvu pomeni ˝brez natrija˝. Za izboljšanje sledljivosti granulocitne kolonije spodbujajočih faktorjev (G-CSF) je treba v bolnikovi dokumentaciji jasno zabeležiti zaščiteno ime uporabljenega zdravila. MEDSEBOJNO DELOVANJE ZDRAVIL IN DRUGE OBLIKE INTERAKCIJ: Zaradi možne občutljivosti hitro se delečih mieloidnih celic za citotoksično kemoterapijo je treba zdravilo Neulasta® dati vsaj 24 ur po aplikaciji citotoksične kemoterapije. Sočasne uporabe zdravila Neulasta® s katerimkoli kemoterapevtskim zdravilom pri bolnikih niso ovrednotili. NEŽELENI UČINKI: Podatki opisujejo neželene učinke, zabeležene v kliničnih preskušanjih in med spontanim poročanjem. Zelo pogosti (. 1/10): glavobol, navzea, bolečina v kosteh. Pogosti (. 1/100 do < 1/10): trombocitopenija, levkocitoza, mišično-skeletna bolečina (mialgija, artralgija, bolečina v okončini, bolečina v hrbtu, mišično-skeletna bolečina, bolečina v vratu), bolečina na mestu injiciranja, bolečina v prsih, ki ne izvira od srca. Občasni (. 1/1.000 do < 1/100): srpastocelična kriza, splenomegalija, ruptura vranice, preobčutljivostne reakcije, anafilaksija, zvišanje sečne kisline, sindrom kapilarne prepustnosti, sindrom akutne dihalne stiske, pljučne neželene reakcije (intersticijska pljučnica, pljučni edem, pljučni infiltrati in pljučna fibroza), Sweetov sindrom (akutna febrilna dermatoza), kožni vaskulitis, reakcije na mestu injiciranja, zvišanje laktat-dehidrogenaze in alkalne fosfataze, prehodno zvišanje jetrnih funkcijskih testov za ALT ali AST, glomerulonefritis. FARMACEVTSKI PODATKI: Shranjujte v hladilniku (2°C – 8°C ). Ne zamrzujte. Zdravilo Neulasta® sme biti izpostavljeno sobni temperaturi (ne nad 30°C) za enkratno obdobje, ki ne sme preseči 72 ur. Zdravilo Neulasta® ni kompatibilno z raztopinami natrijevega klorida. NAČIN IN REŽIM PREDPISOVANJA TER IZDAJE ZDRAVILA: Predpisovanje in izdaja zdravila je le na recept s posebnim režimom – H/Rp. IMETNIK DOVOLJENJA ZA PROMET: Amgen Europe B.V., 4817 ZK Breda, Nizozemska. Dodatna pojasnila lahko dobite v lokalni pisarni: Amgen zdravila d.o.o., Šmartinska 140, SI-1000 Ljubljana. DATUM ZADNJE REVIZIJE BESEDILA: Maj 2015. DATUM PRIPRAVE INFORMACIJE: April 2016. Podrobni podatki o tem zdravilu so na voljo na spletni strani Evropske agencije za zdravila http://www.ema.europa.eu/. Literatura: 1.) Povzetek glavnih značilnosti zdravila Neulasta®, Amgen, 2015. Iclusig® (ponatinib) Ključ do učinkovitega zdravljenja bolnikov s KML in Ph + ALL Zdravilo Iclusig® je peroralni zaviralec tirozin-kinaze (TKI) za doziranje enkrat dnevno z učinkovitim delovanjem pri odraslih bolnikih s KML in Ph+ ALL1 Za bolnike s kronično mieloidno levkemijo (KML) v kronični, pospešeni ali blastni fazi, ki: • so odporni na dasatinib ali nilotinib ali • ne prenašajo dasatiniba ali nilotiniba in pri katerih nadaljnje zdravljenje z imatinibom ni klinično ustrezno ali • imajo mutacijo T315I Za bolnike z akutno limfoblastno levkemijo s prisotnim kromosomom Philadelphia (Ph+ ALL), ki: • so odporni na dasatinib ali • ne prenašajo dasatiniba in pri katerih nadaljnje zdravljenje z imatinibom ni klinično ustrezno ali • imajo mutacijo T315I Predstavnik: Angelini Pharma d.o.o. Koprska ulica 108 A, Ljubljana Iclusig Farmakoterapie 210x280.indd 1 27/10/15 10:04 Erbitux 5 mg/ml raztopina za infundiranje Skrajšan povzetek glavnih znaËilnosti zdravila Sestava: En ml raztopine za infundiranje vsebuje 5 mg cetuksimaba in pomožne snovi. Cetuksimab je himerno monoklonsko IgG1 protitelo. Terapevtske indikacije: Zdravilo Erbitux je indicirano za zdravljenje bolnikov z metastatskim kolorektalnim rakom z ekspresijo receptorjev EGFR in nemutiranim tipom RAS v kombinaciji s kemoterapijo na osnovi irinotekana, kot primarno zdravljenje v kombinaciji s FOLFOX in kot samostojno zdravilo pri bolnikih, pri katerih zdravljenje z oksaliplatinom in zdravljenje na osnovi irinotekana ni bilo uspešno in pri bolnikih, ki ne prenašajo irinotekana. Zdravilo Erbitux je indicirano za zdravljenje bolnikov z rakom skvamoznih celic glave in vratu v kombinaciji z radioterapijo za lokalno napredovalo bolezen in v kombinaciji s kemoterapijo na osnovi platine za ponavljajoËo se in/ali metastatsko bolezen. Odmerjanje in naËin uporabe: Zdravilo Erbitux pri vseh indikacijah infundirajte enkrat na teden. Pred prvo infuzijo mora bolnik prejeti premedikacijo z antihistaminikom in kortikosteroidom najmanj 1 uro pred uporabo cetuksimaba. ZaËetni odmerek je 400 mg cetuksimaba na m2 telesne površine. Vsi naslednji tedenski odmerki so vsak po 250 mg/m2 . Kontraindikacije: Zdravilo Erbitux je kontraindicirano pri bolnikih z znano hudo preobËutljivostno reakcijo (3. ali 4. stopnje) na cetuksimab. Kombinacija zdravila Erbitux s kemoterapijo, ki vsebuje oksaliplatin, je kontraindicirana pri bolnikih z metastatskim kolorektalnim rakom z mutiranim tipom RAS ali kadar status RAS ni znan. Posebna opozorila in previdnostni ukrepi: Pojav hude reakcije, povezane z infundiranjem, zahteva takojšnjo in stalno ukinitev terapije s cetuksimabom. »e pri bolniku nastopi blaga ali zmerna reakcija, povezana z infundiranjem, lahko zmanjšate hitrost infundiranja. PriporoËljivo je, da ostane hitrost infundiranja na nižji vrednosti tudi pri vseh naslednjih infuzijah. »e se pri bolniku pojavi kožna reakcija, ki je ne more prenašati, ali huda kožna reakcija (. 3. stopnje po kriterijih CTCAE), morate prekiniti terapijo s cetuksimabom. Z zdravljenjem smete nadaljevati le, Ëe se je reakcija izboljšala do 2. stopnje. »e ugotovite intersticijsko bolezen pljuË, morate zdravljenje s cetuksimabom prekiniti, in bolnika ustrezno zdraviti. Zaradi možnosti pojava znižanja nivoja elektrolitov v serumu se pred in periodiËno med zdravljenjem s cetuksimabom priporoËa doloËanje koncentracije elektrolitov v serumu. Pri bolnikih, ki prejemajo cetuksimab v kombinaciji s kemoterapijo na osnovi platine, obstaja veËje tveganje za pojav hude nevtropenije. Takšne bolnike je potrebno skrbno nadzorovati. Pri predpisovanju cetuksimaba je treba upoštevati kardiovaskularno stanje in indeks zmogljivosti bolnika in soËasno dajanje kardiotoksiËnih uËinkovin kot so fluoropirimidini. »e je diagnoza ulcerativnega keratitisa potrjena, je treba zdravljenje s cetuksimabom prekiniti ali ukiniti. Cetuksimab je treba uporabljati previdno pri bolnikih z anamnezo keratitisa, ulcerativnega keratitisa ali zelo suhih oËi. Cetuksimaba ne uporabljajte za zdravljenje bolnikov s kolorektalnim rakom, Ëe imajo tumorje z mutacijo RAS ali pri katerih je tumorski status RAS neznan. Interakcije: Pri kombinaciji s fluoropirimidini se je v primerjavi z uporabo fluoropirimidinov, kot monoterapije, poveËala pogostnost srËne ishemije, vkljuËno z miokardnim infarktom in kongestivno srËno odpovedjo ter pogostnost sindroma dlani in stopal. V kombinaciji s kemoterapijo na osnovi platine se lahko poveËa pogostnost hude levkopenije ali hude nevtropenije. V kombinaciji s kapecitabinom in oksaliplatinom (XELOX) se lahko poveËa pogostnost hude driske. Neželeni uËinki: Zelo pogosti (. 1/10): hipomagneziemija, poveËanje ravni jetrnih encimov, kožne reakcije, blage ali zmerne reakcije povezane z infundiranjem, mukozitis, v nekaterih primerih resen. Pogosti (. 1/100 do < 1/10): dehidracija, hipokalciemija, anoreksija, glavobol, konjunktivitis, driska, navzeja, bruhanje, hude reakcije povezane z infundiranjem, utrujenost. Posebna navodila za shranjevanje: Shranjujte v hladilniku (2 °C -8 °C). Pakiranje: 1 viala z 20 ml ali 100 ml raztopine. NaËin in režim izdaje: Izdaja zdravila je le na recept-H. Imetnik dovoljenja za promet: Merck KGaA, 64271 Darmstadt, NemËija. Datum zadnje revizije besedila: november 2014. Pred predpisovanjem zdravila natanËno preberite celoten Povzetek glavnih znaËilnosti zdravila. Samo za strokovno javnost. Podrobnejše informacije so na voljo pri predstavniku imetnika dovoljenja za promet z zdravilom: Merck d.o.o., Ameriška ulica 8, 1000 Ljubljana, tel.: 01 560 3810, faks: 01 560 3830, el. pošta: info@merck.si www.merckserono.net www.Erbitux-international.com PM-ONC-05/2015 /13.10.2015 DVOJNO ZAVIRANJE. VEČJA UČINKOVITOST. Skrajšan povzetek glavnih značilnosti zdravila COTELLIC: Za to zdravilo se izvaja dodatno spremljanje varnosti. Tako bodo hitreje na voljo nove informacije o njegovi varnosti. Zdravstvene delavce naprošamo, da poročajo o katerem koli domnevnem neželenem učinku zdravila. Kako poročati o neželenih učinkih, si poglejte skrajšani povzetek glavnih značilnosti zdravila pod ‘’Poročanje o domnevnih neželenih učinkih’’. Ime zdravila: Cotellic 20 mg filmsko obložene tablete. Kakovostna in količinska sestava: Ena filmsko obložena tableta vsebuje kobimetinibijev hemifumarat, kolikor ga ustreza 20 mg kobimetiniba. Pomožna snov z znanim učinkom: Ena filmsko obložena tableta vsebuje 36 mg laktoze monohidrata. Terapevtske indikacije: Zdravilo Cotellic je v kombinaciji z vemurafenibom indicirano za zdravljenje odraslih bolnikov z neoperabilnim ali metastatskim melanomom, ki ima mutacijo BRAF V600. Odmerjanje in način uporabe: Zdravljenje z zdravilom Cotellic v kombinaciji z vemurafenibom sme uvesti in nadzorovati le usposobljen zdravnik, ki ima izkušnje z uporabo zdravil proti raku. Pred začetkom zdravljenja je treba z validirano preiskavo potrditi, da ima bolnik melanom z mutacijo BRAF V600. Odmerjanje: Vsak odmerek obsega tri 20-mg tablete (60 mg) in ga je treba vzeti enkrat na dan 21 dni zapored, temu sledi 7-dnevni premor. Zdravljenje z zdravilom Cotellic je treba nadaljevati, dokler bolniku ne koristi več oziroma do pojava nesprejemljive toksičnosti. Če bolnik izpusti odmerek, ga lahko vzame do 12 ur pred naslednjim odmerkom, da ohrani shemo enkrat na dan. Če bolnik po uporabi zdravila Cotellic bruha, tisti dan ne sme vzeti dodatnega odmerka, temveč mora zdravljenje nadaljevati naslednji dan, kot je predpisano. Splošne prilagoditve odmerka: Odločitev za zmanjšanje odmerka zdravila Cotellic ali vemurafeniba mora temeljiti na zdravnikovi oceni varnosti in prenašanja pri posameznem bolniku. Ko je bil odmerek enkrat zmanjšan, se ga kasneje ne sme več povečati. Nasvet za prilagoditev odmerka v primeru disfunkcije levega prekata: Če so srčni simptomi posledica zdravila Cotellic in se po prehodni prekinitvi njegove uporabe ne izboljšajo, je treba razmisliti o trajnem prenehanju zdravljenja z zdravilom Cotellic. Nasvet za prilagoditev odmerka zdravila Cotellic med uporabo z vemurafenibom: Jetrna laboratorijska odstopanja: Stopnja 3: Zdravilo Cotellic je treba nadaljevati v predpisanem odmerku. Odmerek vemurafeniba je mogoče zmanjšati, kot je klinično primerno. Stopnja 4: Zdravljenje z zdravilom Cotellic in zdravljenje z vemurafenibom je treba prekiniti. Za dodatna navodila glejte celotni povzetek glavnih značilnosti zdravila Cotellic. Zvišanja kreatin-fosfokinaze (CPK): Za obvladovanje nesimptomatskih zvišanj CPK odmerka zdravila Cotellic ni treba prilagoditi ali prekiniti. Fotosenzibilnost: Fotosenzibilnost stopnje . 2 je treba obvladovati s podpornim zdravljenjem. Fotosenzibilnost stopnje 2 ali stopnje . 3: zdravili Cotellic in vemurafenib je treba prekiniti, dokler se ne zmanjša na stopnjo . 1. Zdravljenje je mogoče znova začeti brez spremembe odmerka zdravila Cotellic. Odmerjanje vemurafeniba je treba zmanjšati, kot je klinično primerno; za dodatne informacije glejte povzetek glavnih značilnosti vemurafeniba. Izpuščaj: Izpuščaj se lahko pojavi tako med zdravljenjem z zdravilom Cotellic kot med zdravljenjem z vemurafenibom. Odmerek zdravila Cotellic in/ali vemurafeniba je mogoče začasno prekiniti in/ali zmanjšati, kot je klinično primerno. Za dodatna navodila glejte celotni povzetek glavnih značilnosti zdravila Cotellic. Podaljšanje inter vala QT: Če interval QTc med zdravljenjem preseže 500 ms, prosimo, glejte povzetek glavnih značilnosti vemurafeniba. Sprememba odmerkov zdravila Cotellic ni potrebna, kadar se ta uporablja v kombinaciji z vemurafenibom. Posebne populacije bolnikov: Bolnikom, starim . 65 let, odmerka ni treba prilagoditi. Pri bolnikih s hudo okvaro ledvic je treba zdravilo Cotellic uporabljati previdno. Pri bolnikih z zmerno do hudo okvaro jeter je treba zdravilo Cotellic uporabljati previdno. Varnost in učinkovitost zdravila Cotellic pri otrocih in mladostnikih, mlajših od 18 let, nista ugotovljeni. Način uporabe: Zdravilo Cotellic je za peroralno uporabo. Tablete je treba zaužiti cele, z vodo. Lahko se jemljejo skupaj s hrano ali brez nje. Kontraindikacije: Preobčutljivost na zdravilno učinkovino ali katero koli pomožno snov. Posebna opozorila in previdnostni ukrepi: Zdravilo Cotellic v kombinaciji z vemurafenibom pri bolnikih, katerih bolezen je napredovala med zdravljenjem z zaviralcem BRAF: Podatkov pri teh bolnikih je malo. Ti kažejo, da je učinkovitost kombinacije pri teh bolnikih manjša. Zato je treba razmisliti o drugih možnostih zdravljenja pred uvedbo kombinacije. Zdravilo Cotellic v kombinaciji z vemurafenibom pri bolnikih z zasevki v možganih: Varnost in učinkovitost kombinacije zdravila Cotellic in vemurafeniba pri teh bolnikih ni bila ocenjena. Intrakranialna aktivnost kobimetiniba trenutno ni poznana. Serozna retinopatija: Pri bolnikih, zdravljenih z zaviralci MEK, vključno z zdravilom Cotellic, so opažali serozno retinopatijo. Večina primerov je bila opisana kot horioretinopatija ali odstop mrežnice. Večina dogodkov, opaženih v kliničnih preskušanjih, je po prekinitvi ali zmanjšanju odmerka izzvenela ali se izboljšala na nesimptomatsko stopnjo 1. Bolnike je treba na vsakem pregledu oceniti glede simptomov novih motenj vida ali poslabšanja obstoječih motenj vida. V primeru simptomov novih motenj vida ali poslabšanju obstoječih je priporočljiv oftalmološki pregled. Serozno retinopatijo je mogoče obvladati s prekinitvijo zdravljenja, zmanjšanjem odmerka ali prenehanjem zdravljenja. Disfunkcija levega prekata: Pri bolnikih, ki so prejemali zdravilo Cotellic, so poročali o zmanjšanju iztisnega deleža levega prekata (LVEF) v primerjavi z izhodiščem. LVEF je treba izmeriti pred začetkom zdravljenja za določitev izhodiščne vrednosti, nato pa ga kontrolirati po prvem mesecu zdravljenja ter vsaj na 3 mesece oziroma kot je klinično indicirano, do prenehanja zdravljenja. Zmanjšanje LVEF od izhodišča je mogoče obvladati s prekinitvijo zdravljenja, zmanjšanjem odmerka ali prenehanjem zdravljenja. Bolnikov z izhodiščnim LVEF pod spodnjo mejo normalne vrednosti (SMN) za ustanovo ali pod 50 % niso proučevali. Jetrna laboratorijska odstopanja: Jetrna laboratorijska odstopanja se lahko pojavijo tako med uporabo zdravila Cotellic v kombinaciji z vemurafenibom kot med samostojnim zdravljenjem z vemurafenibom. Pri bolnikih, zdravljenih s kombinacijo zdravila Cotellic in vemurafeniba, so opažali jetrna laboratorijska odstopanja, zlasti zvišanje ALT, AST in AF. Jetrna laboratorijska odstopanja je treba kontrolirati z laboratorijskimi preiskavami jeter pred začetkom kombiniranega zdravljenja in vsak mesec med zdravljenjem, lahko pa tudi pogosteje, če je klinično indicirano. Laboratorijska odstopanja stopnje 3 je treba obvladati s prekinitvijo uporabe vemurafeniba ali zmanjšanjem odmerka. Jetrna laboratorijska odstopanja stopnje 4 se obvlada s prekinitvijo zdravljenja, zmanjšanjem odmerka ali prenehanjem zdravljenja z zdravilom Cotellic in z vemurafenibom. Driska: Pri bolnikih, zdravljenih z zdravilom Cotellic, so poročali o primerih driske stopnje . 3 in resni driski. Drisko je treba obvladati z antidiaroiki in podpornim zdravljenjem. V primeru driske stopnje . 3, ki se pojavi kljub podpornemu zdravljenju, je treba obe zdravili, Cotellic in vemurafenib, prekiniti, dokler se driska ne izboljša na stopnjo . 1. Če se driska stopnje . 3 ponovi, je treba odmerek zdravila Cotellic in vemurafeniba zmanjšati. Intoleranca za laktozo: Zdravilo vsebuje laktozo. Bolniki z redko dedno intoleranco za galaktozo, laponsko obliko pomanjkanja laktaze ali malabsorpcijo glukoze/ galaktoze se morajo posvetovati z zdravnikom in se z njim pogovoriti, ali zanje koristi zdravljenja odtehtajo tveganje. Podaljšanje intervala QT: Če interval QTc med zdravljenjem preseže 500 ms, prosimo, glejte povzetka glavnih značilnosti vemurafeniba. Medsebojno delovanje z drugimi zdravili in druge oblike interakcij: Učinki drugih zdravil na kobimetinib: Zaviralci CYP3A4: Med zdravljenjem s kobimetinibom se izogibajte sočasni uporabi močnih zaviralcev CYP3A. Če se sočasni uporabi močnega zaviralca CYP3A ni mogoče izogniti, je treba bolnike skrbno nadzirati glede varnosti. Previdnost je potrebna, če se kobimetinib uporablja sočasno z zmernimi zaviralci CYP3A. Če se kobimetinib uporablja sočasno z zmernim zaviralcem CYP3A, je treba bolnike skrbno nadzirati glede varnosti. Induktorji CYP3A4: Treba se je izogibati sočasni uporabi z zmernimi in močnimi induktorji CYP3A. Razmisliti je treba o uporabi drugih zdravil, ki CYP3A inducirajo le malo ali sploh ne. Ker se med sočasno uporabo zmernih do močnih induktorjev CYP3A koncentracija kobimetiniba verjetno bistveno zniža, se lahko njegova učinkovitost pri bolniku poslabša. Zaviralci P-glikoproteina: Sočasna uporaba zaviralcev P-gp, npr. ciklosporina in verapamila, lahko zviša koncentracijo kobimetiniba v plazmi. Učinki kobimetiniba na druga zdravila: Substrati CYP3A in CYP2D6: Klinična študija medsebojnega delovanja zdravil pri onkoloških bolnikih je pokazala, da se koncentraciji midazolama in dekstrometorfana v plazmi v prisotnosti kobimetiniba nista spremenili. Substrati CYP1A2: In vitro je kobimetinib potencialen induktor CYP1A2 in lahko zato zmanjša izpostavljenost substratom tega encima, npr. teofilinu. Substrati BCRP: In vitro kobimetinib zmerno zavira BCRP. Klinično pomembnega zavrtja BCRP na ravni črevesja ni mogoče izključiti. Druga zdravila proti raku: vemurafenib: Pri bolnikih z neoperabilnim ali metastatskim melanomom ni dokazov o klinično pomembnem medsebojnem delovanju med kobimetinibom in vemurafenibom, zato prilagoditve odmerkov niso potrebne. Vpliv kobimetiniba na transportne sisteme zdravil: Študije in vitro kažejo, da kobimetinib ni substrat jetrnih privzemnih prenašalcev OATP1B1, OATP1B3 in OCT1, vendar pa jih rahlo zavira. Klinični pomen teh izsledkov ni raziskan. Pediatrična populacija: Študije medsebojnega delovanja so izvedli le pri odraslih. Neželeni učinki: Neželeni učinki pri bolnikih, zdravljenih z zdravilom Cotellic v kombinaciji z vemurafenibom: Zelo pogosti: anemija, serozna retinopatija, hipertenzija, krvavitev, driska, navzea, bruhanje, fotosenzibilnost, izpuščaj, makulopapulozen izpuščaj, akneiformni dermatitis, hiperkeratoza, zvišana telesna temperatura, zvišanja CPK, ALT, AST, gama-glutamiltransferaze (GGT) in AF v krvi. Pogosti: bazalnocelični karcinom, ploščatocelični karcinom kože, keratoakantom, dehidracija, hipofosfatemija, hiponatriemija, hiperglikemija, zamegljen vid, okvara vida, pnevmonitis, mrzlica, zmanjšan iztisni delež in zvišanje bilirubina v krvi. Poročanje o domnevnih neželenih učinkih: Poročanje o domnevnih neželenih učinkih zdravila po izdaji dovoljenja za promet je pomembno. Omogoča namreč stalno spremljanje razmerja med koristmi in tveganji zdravila. Od zdravstvenih delavcev se zahteva, da poročajo o katerem koli domnevnem neželenem učinku zdravila na: Univerzitetni klinični center Ljubljana, Interna klinika, Center za zastrupitve, Zaloška cesta 2, SI-1000 Ljubljana, Faks: + 386 (0)1 434 76 46, e-pošta: farmakovigilanca@kclj.si. Režim izdaje zdravila: Rp/Spec. Imetnik dovoljenja za promet: Roche Registration Limited, 6 Falcon Way, Shire Park, Welwyn Garden City, AL7 1TW, Velika Britanija. Verzija: 1.0/15. Informacija pripravljena: april 2016. Samo za strokovno javnost. Skrajšan povzetek glavnih značilnosti zdravila ZELBORAF: Za to zdravilo se izvaja dodatno spremljanje varnosti. Tako bodo hitreje na voljo nove informacije o njegovi varnosti. Zdravstvene delavce naprošamo, da poročajo o katerem koli domnevnem neželenem učinku zdravila. Kako poročati o neželenih učinkih, si poglejte skrajšani povzetek glavnih značilnosti zdravila pod ‘’Poročanje o domnevnih neželenih učinkih’’. Ime zdravila: Zelboraf 240 mg filmsko obložene tablete. Kakovostna in količinska sestava: Ena tableta vsebuje 240 mg vemurafeniba (v obliki precipitata vemurafeniba in hipromeloze acetat sukcinata). Terapevtske indikacije: Vemurafenib je indiciran za samostojno zdravljenje odraslih bolnikov z neresektabilnim ali metastatskim melanomom, s pozitivno mutacijo BRAF V600. Odmerjanje in način uporabe: Zdravljenje z vemurafenibom mora uvesti in nadzorovati usposobljen zdravnik, ki ima izkušnje z uporabo zdravil za zdravljenje raka. Odmerjanje: Priporočeni odmerek vemurafeniba je 960 mg (4 tablete po 240 mg) dvakrat na dan (to ustreza celotnemu dnevnemu odmerku 1920 mg). Vemurafenib lahko vzamemo s hrano ali brez nje, izogibati pa se moramo stalnemu jemanju obeh dnevnih odmerkov na prazen želodec. Zdravljenje z vemurafenibom moramo nadaljevati do napredovanja bolezni ali pojava nesprejemljive toksičnosti. Če bolnik izpusti odmerek, ga lahko vzame do 4 ure pred naslednjim odmerkom za ohranitev sheme dvakrat na dan. Obeh odmerkov pa ne sme vzeti hkrati. Če bolnik po zaužitju vemurafeniba bruha, ne sme vzeti dodatnega odmerka zdravila, ampak mora z zdravljenjem normalno nadaljevati. Prilagoditve odmerjanja: Za obvladovanje neželenih učinkov ali ob podaljšanju intervala QTc je potrebno zmanjšanje odmerka, začasna prekinitev in/ali dokončno prenehanje zdravljenja (za podrobnosti o prilagoditvi odmerka, prosimo glejte SmPC zdravila). Zmanjšanje odmerka pod 480 mg dvakrat na dan ni priporočljivo. Če se pri bolniku pojavi ploščatocelični karcinom kože, priporočamo nadaljevanje zdravljenja brez zmanjšanja odmerka vemurafeniba. Posebne populacije: Za bolnike, starejše od 65 let, prilagajanje odmerka ni potrebno. O bolnikih z okvaro ledvic ali jeter je na voljo malo podatkov. Bolnike s hudo okvaro ledvic ali z zmerno do hudo okvaro jeter je treba pozorno spremljati. Varnost in učinkovitost vemurafeniba pri otrocih in mladostnikih, mlajših od 18 let, še nista bili dokazani. Podatkov ni na voljo. Način uporabe: Tablete vemurafeniba je treba zaužiti cele, z vodo. Ne sme se jih žvečiti ali zdrobiti. Kontraindikacije: Preobčutljivost na zdravilno učinkovino ali katerokoli pomožno snov. Posebna opozorila in previdnostni ukrepi: Pred uporabo vemurafeniba je treba z validirano preiskavo potrditi, da ima bolnik tumor s pozitivno mutacijo BRAF V600. Dokazi o učinkovitosti in varnosti vemurafeniba pri bolnikih s tumorji z izraženo redko BRAF V600 mutacijo, ki ni V600E ali V600K, niso prepričljivi. Vemurafeniba se ne sme uporabljati pri bolnikih z malignim melanomom, ki ima divji tip BRAF. Preobčutljivostne reakcije: V povezavi z vemurafenibom so bile opisane resne preobčutljivostne reakcije, vključno z anafilaksijo. Hude preobčutljivostne reakcije lahko vključujejo Stevens-Johnsonov sindrom, generaliziran izpuščaj, eritem ali hipotenzijo. Pri bolnikih, pri katerih se pojavijo resne preobčutljivostne reakcije, je treba zdravljenje z vemurafenibom dokončno opustiti. Kožne reakcije: Pri bolnikih, ki so prejemali vemurafenib, so v ključnem kliničnem preskušanju poročali o hudih kožnih reakcijah, vključno z redkim Stevens-Johnsonovim sindromom in toksično epidermalno nekrolizo. Po prihodu vemurafeniba na trg so v povezavi z njim poročali o reakciji na zdravilo z eozinofilijo in sistemskimi simptomi (DRESS, Drug Reaction with Eosinophilia and Systemic Symptoms). Pri bolnikih, pri katerih se pojavi huda kožna reakcija, je treba zdravljenje z vemurafenibom dokončno opustiti. Povečanje toksičnosti obsevanja: Pri bolnikih, ki so se pred, med ali po zdravljenju z vemurafenibom zdravili z obsevanjem, so poročali o primerih vnetnih reakcij na mestu obsevanja (t.i. radiation recall) in povečane občutljivosti na obsevanje. Večina primerov je bila po naravi kožnih, a nekaj primerov, ki je vključevalo visceralne organe, je imelo smrtni izid. Pri sočasni ali zaporedni uporabi vemurafeniba in obsevanja je potrebna previdnost. Podaljšanje inter vala QT: V nekontrolirani, odprti študiji faze II pri predhodno zdravljenih bolnikih z metastatskim melanomom, so opazili podaljšanje intervala QT, odvisnega od izpostavljenosti vemurafenibu. Podaljšanje intervala QT lahko poveča tveganje za ventrikularne aritmije, vključno s t. i. Torsade de Pointes. Z vemurafenibom ni priporočljivo zdraviti bolnikov z elektrolitskimi motnjami (vključno z magnezijem), ki jih ni mogoče odpraviti, bolnikov s sindromom dolgega intervala QT in bolnikov, zdravljenih z zdravili, ki podaljšajo interval QT. Pred zdravljenjem z vemurafenibom, en mesec po zdravljenju in po spremembi odmerka je treba pri vseh bolnikih posneti elektrokardiogram (EKG) in kontrolirati elektrolite (vključno z magnezijem). Nadaljnje kontrole so priporočljive predvsem pri bolnikih z zmerno do hudo jetrno okvaro, in sicer mesečno prve 3 mesece zdravljenja, potem pa na 3 mesece oziroma pogosteje, če je to klinično indicirano. Zdravljenja z vemurafenibom ni priporočljivo uvesti pri bolnikih, ki imajo interval QTc > 500 milisekund (ms). Bolezni oči: Poročali so o resnih neželenih učinkih na očeh, vključno z uveitisom, iritisom in zaporo mrežnične vene. Bolnikom je treba oči redno kontrolirati glede morebitnih neželenih učinkov na očeh. Ploščatocelični karcinom kože: Pri bolnikih, zdravljenih z vemurafenibom, so bili opisani primeri ploščatoceličnega karcinoma kože, vključno s ploščatoceličnim karcinomom, opredeljenim kot keratoakantom ali mešani keratoakantom. Priporočljivo je, da vsi bolniki pred uvedbo zdravljenja opravijo dermatološki pregled in da so med zdravljenjem deležni rednih kontrol. Vsako sumljivo spremembo je treba izrezati, poslati na histopatološko oceno in jo zdraviti v skladu z lokalnimi smernicami. Med zdravljenjem in do šest mesecev po zdravljenju ploščatoceličnega karcinoma mora zdravnik enkrat mesečno pregledati bolnika. Pri bolnikih, ki se jim pojavi ploščatocelični karcinom kože, je priporočljivo nadaljevati zdravljenje brez zmanjšanja odmerka. Nadzor se mora nadaljevati še 6 mesecev po prenehanju zdravljenja z vemurafenibom ali do uvedbe drugega antineoplastičnega zdravljenja. Bolnikom je treba naročiti, naj svojega zdravnika obvestijo o pojavu kakršnih koli sprememb na koži. Ploščatocelični karcinom, ki se ne nahaja na koži: Pri bolnikih, ki so prejemali vemurafenib v kliničnih preskušanjih, so poročali o primerih ploščatoceličnega karcinoma, ki se ne nahaja na koži. Bolnikom je treba pred uvedbo zdravljenja in na 3 mesece med zdravljenjem pregledati glavo in vrat (pregled mora obsegati vsaj ogled ustne sluznice in palpacijo bezgavk). Poleg tega morajo bolniki pred zdravljenjem in na 6 mesecev med zdravljenjem opraviti računalniško tomografijo (CT) prsnega koša. Pred in po končanem zdravljenju ali kadar je klinično indicirano, je priporočljivo opraviti pregled zadnjika in ginekološki pregled (pri ženskah). Po prenehanju zdravljenja z vemurafenibom se mora nadzor glede ploščatoceličnega karcinoma, ki se ne nahaja na koži, nadaljevati še 6 mesecev ali do uvedbe drugega antineoplastičnega zdravljenja. Nenormalne spremembe je treba obravnavati v skladu s klinično prakso. Novi primarni melanom: V kliničnih preskušanjih so poročali o novih primarnih melanomih. Bolnike s takšnimi primeri so zdravili z ekscizijo, bolniki pa so nadaljevali z zdravljenjem brez prilagoditve odmerka. Nadzor nad pojavom kožnih lezij je treba izvajati, kot je navedeno zgoraj pri ploščatoceličnem karcinomu kože. Druge malignosti: Glede na mehanizem delovanja lahko vemurafenib povzroči napredovanje rakov, povezanih z mutacijo RAS. Pred dajanjem vemurafeniba bolnikom, ki so imeli ali imajo raka, povezanega z mutacijo RAS, skrbno razmislite o koristih in tveganjih. Pankreatitis: Pri bolnikih, zdravljenih z zdravilom Zelboraf, so poročali o pankreatitisu. Nepojasnjeno bolečino v trebuhu je treba nemudoma preiskati. Bolnike je treba skrbno spremljati, ko po epizodi pankreatitisa ponovno uvedemo vemurafenib. Poškodbe jeter: Med uporabo vemurafeniba so poročali o poškodbah jeter, vključno s primeri hudih poškodb. Pred uvedbo zdravljenja in mesečno med zdravljenjem oz. kot je klinično indicirano, je treba kontrolirati jetrne encime (transaminaze in alkalno fosfatazo) ter bilirubin. Laboratorijske nepravilnosti je treba obvladati z zmanjšanjem odmerka, prekinitvijo zdravljenja ali prenehanjem zdravljenja (za podrobnosti o prilagoditvi odmerka, prosimo glejte SmPC zdravila). Jetrna okvara: Bolnikom z jetrno okvaro začetnih odmerkov ni treba prilagajati. Bolnike, ki imajo zaradi metastaz v jetrih blago jetrno okvaro in nimajo hiperbilirubinemije, se lahko nadzoruje v skladu s splošnimi priporočili. Podatkov o bolnikih z zmerno do hudo jetrno okvaro je le malo; pri takih bolnikih je izpostavljenost lahko večja. Tako je posebej po prvih tednih zdravljenja potreben skrben nadzor, saj lahko po daljšem obdobju (več tednih) pride do kopičenja. Ledvična okvara: Bolnikom z blago ali zmerno ledvično okvaro začetnih odmerkov ni treba prilagajati. Pri bolnikih z hudo ledvično okvaro je treba vemurafenib uporabljati previdno ter jih pozorno spremljati. Fotosenzibilnost: Pri bolnikih, ki so v kliničnih študijah prejemali vemurafenib, je bila opisana blaga do huda fotosenzibilnost. Vsem bolnikom je treba naročiti, naj se med jemanjem vemurafeniba ne izpostavljajo soncu. V primeru fotosenzibilnosti stopnje 2 (neprenosljivo) ali več so priporočljive prilagoditve odmerka. Ženske v rodni dobi morajo med zdravljenjem in vsaj še 6 mesecev po zdravljenju uporabljati učinkovito kontracepcijsko zaščito. Vemurafenib lahko zmanjša učinkovitost hormonskih kontraceptivov. Sočasno dajanje ipilimumaba: Pri sočasni uporabi ipilimumaba in vemurafeniba so v preskušanju faze I poročali o asimptomatskih zvišanjih transaminaz in bilirubina stopnje 3. Glede na te preliminarne podatke sočasna uporaba ipilimumaba in vemurafeniba ni priporočljiva. Medsebojno delovanje z drugimi zdravili in druge oblike interakcij: Vplivi vemurafeniba na substrate CYP Vemurafenib lahko poveča izpostavljenost v plazmi tistih snovi, ki se presnavljajo pretežno s CYP1A2; v takem primeru se lahko razmisli o prilagoditvi odmerka, če je klinično indicirano. Vemurafenib lahko zmanjša plazemsko izpostavljenost zdravilom, ki se presnavljajo pretežno s CYP3A4. Tako je lahko učinkovitost kontracepcijskih tablet, ki se presnavljajo s CYP3A4 in se uporabljajo sočasno z vemurafenibom, zmanjšana. Pri substratih CYP3A4, ki imajo ozko terapevtsko okno, se lahko razmisli o prilagoditvi odmerka, če je klinično indicirano. Zaenkrat še ni znano ali lahko vemurafenib pri 100 µM koncentraciji v plazmi, ki je bila opažena pri bolnikih v stanju dinamičnega ravnovesja (približno 50 µg/ml), zmanjša plazemske koncentracije sočasno dajanih substratov CYP2B6, kot je bupropion. Kadar se vemurafenib pri bolnikih z melanonom uporabi hkrati z varfarinom (CYP2C9), je potrebna previdnost. Tveganja za klinično pomemben učinek na sočasno uporabljene učinkovine, ki so substrati CYP2C8, pa ni mogoče izključiti. Zaradi dolge razpolovne dobe vemurafeniba je mogoče, da popolnega inhibitornega učinka vemurafeniba na sočasno dajano zdravilo ne opazimo, dokler ne mine 8 dni zdravljenja z vemurafenibom. Po končanem zdravljenju z vemurafenibom bo morda potreben 8-dnevni premor, da se izognemo interakcijam z nadaljnjim zdravljenjem. Zdravljenje z obsevanjem: Pri bolnikih, zdravljenih z vemurafenibom, so poročali o povečanju toksičnosti obsevanja. V večini primerov so bolniki prejeli protokole obsevanja z 2 Gy/dan ali več (hipofrakcionirane protokole). Vpliv vemurafeniba na transportne sisteme zdravil Ob sočasni uporabi vemurafeniba in substrata P-gp je potrebna previdnost. Pri uporabi zdravil, ki so substrati P-gp in imajo ozko terapevtsko okno (npr. digoksina, dabigatran eteksilata, aliskirena), je treba razmisliti o dodatnem spremljanju koncentracije zdravila. Učinki vemurafeniba na zdravila, ki so substrati BCRP, niso znani. Možnosti, da vemurafenib morda poveča izpostavljenost zdravil, ki se prenašajo z BCRP, ni mogoče izključiti. Možen vpliv vemurafeniba na druge prenašalce trenutno ni znan. Vplivi sočasno uporabljenih zdravil na vemurafenib Študije in vitro kažejo, da sta presnova s CYP3A4 in glukuronidacija odgovorni za presnovo vemurafeniba. Zdi se, da je tudi izločanje z žolčem pomembna pot izločanja. Vemurafenib je treba uporabljati previdno v kombinaciji z močnimi inhibitorji CYP3A4, glukuronidacije in/ali prenašalnih beljakovin (npr. ritonavirjem, sakvinavirjem, telitromicinom, ketokonazolom, itrakonazolom, vorikonazolom, posakonazolom, nefazodonom, atazanavirjem). Sočasna uporaba močnih induktorjev P-gp, glukuronidacije, in/ali CYP3A4 (npr. rifampicina, rifabutina, karbamazepina, fenitoina ali šentjanževke [Hypericum perforatum]) lahko vodi v suboptimalno izpostavljenost vemurafenibu in se ji je treba izogibati. Študije in vitro so pokazale, da je vemurafenib substrat sekretornih prenašalcev, P-gp in BCRP. Vplivi induktorjev in inhibitorjev P-gp in BCRP na izpostavljenost vemurafenibu niso znani. Ne moremo pa izključiti možnosti, da imajo lahko zdravila, ki vplivajo na P-gp (npr. verapamil, ciklosporin, ritonavir, kinidin, itrakonazol) ali BCRP (npr. ciklosporin, gefitinib), vpliv na farmakokinetiko vemurafeniba. Za zdaj ni znano, ali je vemurafenib substrat tudi za druge beljakovinske prenašalce. Neželeni učinki: Med najpogostejšimi neželenimi učinki (> 30 %), o katerih so poročali v zvezi z vemurafenibom, so artralgija, utrujenost, kožni izpuščaj, fotosenzibilnostna reakcija, navzea, alopecija in srbenje. Zelo pogosto je bil opisan ploščatocelični karcinom kože. Sledijo najpogostejši neželeni učinki, ki so se pojavili pri bolnikih, zdravljenih z vemurafenibom v študiji faze II in III in dogodki iz varnostnih poročil vseh preskušanj in obdobja po prihodu zdravila na trg. Zelo pogosti: ploščatocelični karcinom kože, seboroična keratoza, kožni papilom, zmanjšanje teka, glavobol, disgevzija, kašelj, driska, bruhanje, slabost, zaprtost, fotosenzibilna reakcija, aktinična keratoza, kožni izpuščaj, makulo-papulozen izpuščaj, papulozen izpuščaj, srbenje, hiperkeratoza, eritem, alopecija, suha koža, sončne opekline, artralgija, mialgija, bolečina v okončini, mišično-skeletne bolečine, bolečine v hrbtu, utrujenost, pireksija, periferni edem, astenija, zvišanje GGT. Pogosti: folikulitis, bazalnocelični karcinom, novi primarni melanom, ohromelost sedmega živca, omotica, uveitis, sindrom palmarno-plantarne eritrodisestezije, panikulitis (vključno z nodoznim eritemom), pilarna keratoza, artritis, zvišanje ALT, alkalne fosfataze, bilirubina in izguba telesne mase, podaljšanje QT. Posebne populacije: Pri starejših bolnikih (. 65 let) je možna večja verjetnost neželenih učinkov, vključno s ploščatoceličnim karcinomom kože, zmanjšanjem teka in motnjami srčnega ritma. Med neželene učinke stopnje 3, ki so bili med kliničnimi preskušanji vemurafeniba pri ženskah opisani pogosteje kot pri moških, spadajo kožni izpuščaj, artralgija in fotosenzibilnost. Poročanje o domnevnih neželenih učinkih: Poročanje o domnevnih neželenih učinkih zdravila po izdaji dovoljenja za promet je pomembno. Omogoča namreč stalno spremljanje razmerja med koristmi in tveganji zdravila. Od zdravstvenih delavcev se zahteva, da poročajo o katerem koli domnevnem neželenem učinku zdravila na: Univerzitetni klinični center Ljubljana, Interna klinika, Center za zastrupitve, Zaloška cesta 2, SI-1000 Ljubljana, Faks: + 386 (0)1 434 76 46, e-pošta: farmakovigilanca@kclj.si. Režim izdaje zdravila: Rp/Spec. Imetnik dovoljenja za promet: Roche Registration Limited, 6 Falcon Way, Shire Park, Welwyn Garden City, AL7 1TW, Velika Britanija. Verzija: 4.0/15. Informacija pripravljena: april 2016. Samo za strokovno javnost. PG-21-0416-ZEL-TG DODATNE INFORMACIJE SO NA VOLJO PRI: Roche farmacevtska družba d.o.o., Vodovodna cesta 109, 1000 Ljubljana. DVOJNO ZAVIRANJE. 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Open access Papers are published electronically as open access on www.degruyter.com/view/j/raon, also papers accepted for publication as E-ahead of print. BISTVENI PODATKI IZ POVZETKA GLAVNIH ZNACˇILNOSTI ZDRAVILA Za to zdravilo se izvaja dodatno spremljanje varnosti. Tako bodo hitreje na voljo nove informacije o njegovi varnosti. Zdravstvene delavce naprošamo, da porocˇajo o kateremkoli domnevnem neželenem ucˇinku zdravila. Glejte poglavje 4.8 povzetka glavnih znacˇilnosti zdravila, kako porocˇati o neželenih ucˇinkih. Sestava in oblika zdravila: Ena kapsula vsebuje 200 mg ali 250 mg krizotiniba. Indikacije: Zdravljenje odraslih bolnikov z napredovalim nedrobnocelicˇnim pljucˇnim rakom (NSCLC - non-small cell lung cancer), ki je ALK (anaplasticˇna limfomska kinaza) pozitiven. Zdravljenje odraslih bolnikov s predhodno zdravljenim, napredovalim NSCLC, ki je ALK pozitiven. Odmerjanje in nacˇin uporabe: Zdravljenje mora uvesti in nadzorovati zdravnik z izkušnjami z uporabo zdravil za zdravljenje rakavih bolezni. Preverjanje prisotnosti ALK: Pri izbiri bolnikov za zdravljenje z zdravilom XALKORI je treba opraviti tocˇno in validirano preverjanje prisotnosti ALK. Odmerjanje: Priporocˇeni odmerek je 250 mg dvakrat na dan (500 mg na dan), bolniki pa morajo zdravilo jemati brez prekinitev. Cˇe bolnik pozabi vzeti odmerek, ga mora vzeti takoj, ko se spomni, razen cˇe do naslednjega odmerka manjka manj kot 6 ur. V tem primeru bolnik pozabljenega odmerka na sme vzeti. Prilagajanja odmerkov: Glede na varnost uporabe zdravila pri posameznem bolniku in kako bolnik zdravljenje prenaša, utegne biti potrebna prekinitev in/ali zmanjšanje odmerka zdravila na 200 mg dvakrat na dan; cˇe je potrebno še nadaljnje zmanjšanje, pa znaša odmerek 250 mg enkrat na dan. Prilagajanje odmerkov pri hematološki in nehematološki (povecˇanje vrednosti AST, ALT, bilirubina; ILD/pnevmonitis; podaljšanje intervala QTc, bradikardija) toksicˇnosti: glejte preglednici 1 in 2 v povzetku glavnih znacˇilnosti zdravila. Okvara jeter: Pri blagi in zmerni okvari je zdravljenje treba izvajati previdno, pri hudi okvari se zdravila ne sme uporabljati. Okvara ledvic: Pri blagi in zmerni okvari prilagajanje zacˇetnega odmerka ni priporocˇeno. Pri hudi okvari ledvic (ki ne zahteva peritonealne dialize ali hemodialize) je zacˇetni odmerek 250 mg peroralno enkrat na dan; po vsaj 4 tednih zdravljenja se lahko povecˇa na 200 mg dvakrat na dan. Starejši bolniki (. 65 let): Prilagajanje zacˇetnega odmerka ni potrebno. Pediatricˇna populacija: Varnost in ucˇinkovitost nista bili dokazani. Nacˇin uporabe: Kapsule je treba pogoltniti cele, z nekaj vode, s hrano ali brez nje. Ne sme se jih zdrobiti, raztopiti ali odpreti. Izogibati se je treba uživanju grenivk, grenivkinega soka ter uporabi šentjanževke. Kontraindikacije: Preobcˇutljivost na krizotinib ali katerokoli pomožno snov. Huda okvara jeter. Posebna opozorila in previdnostni ukrepi: Dolocˇanje statusa ALK: Pomembno je izbrati dobro validirano in robustno metodologijo, da se izognemo lažno negativnim ali lažno pozitivnim rezultatom. Hepatotoksicˇnost: V klinicˇnih študijah so porocˇali o hepatotoksicˇnosti, ki jo je povzrocˇilo zdravilo (vkljucˇno s primeri s smrtnim izidom). Delovanje jeter, vkljucˇno z ALT, AST in skupnim bilirubinom, je treba preveriti enkrat na teden v prvih 2 mesecih zdravljenja, nato pa enkrat na mesec in kot je klinicˇno indicirano. Ponovitve preverjanj morajo biti pogostejše pri povecˇanjih vrednosti stopnje 2, 3 ali 4. Intersticijska bolezen pljucˇ/ pnevmonitis: Lahko se pojavi huda, življenjsko nevarna in/ali smrtna intersticijska bolezen pljucˇ (ILD -interstitial lung disease)/pnevmonitis. Bolnike s simptomi, ki nakazujejo na ILD/pnevmonitis, je treba spremljati, zdravljenje pa prekiniti ob sumu na ILD/pnevmonitis. Podaljšanje intervala QT: Opažali so podaljšanje intervala QTc. Pri bolnikih z obstojecˇo bradikardijo, podaljšanjem intervala QTc v anamnezi ali predispozicijo zanj, pri bolnikih, ki jemljejo antiaritmike ali druga zdravila, ki podaljšujejo interval QT, ter pri bolnikih s pomembno obstojecˇo srcˇno boleznijo in/ali motnjami elektrolitov je treba zdravilo uporabljati previdno; potrebno je redno spremljanje EKG, elektrolitov in delovanja ledvic; preiskavi EKG in elektrolitov je treba opraviti cˇimbližje uporabi prvega odmerka, potem se priporocˇa redno spremljanje. Bradikardija: Lahko se pojavi simptomatska bradikardija (lahko se razvije vecˇ tednov po zacˇetku zdravljenja); izogibati se je treba uporabi krizotiniba v kombinaciji z drugimi zdravili, ki povzrocˇajo bradikardijo; pri simptomatski bradikardiji je treba prilagoditi odmerek. Srcˇno popušcˇanje: Porocˇali so o hudih, življenjsko nevarnih ali smrtnih neželenih ucˇinkih srcˇnega popušcˇanja. Bolnike je treba spremljati glede pojavov znakov in simptomov srcˇnega popušcˇanja in ob pojavu simptomov zmanjšati odmerjanje ali prekinit zdravljenje. Nevtropenija in levkopenija: V klinicˇnih študijah so porocˇali o nevtropeniji, levkopeniji in febrilni nevtropeniji (pri manj kot 0,5 % bolnikov); spremljati je treba popolno krvno sliko (pogostejše preiskave, cˇe se opazijo abnormalnosti stopnje 3 ali 4 ali cˇe se pojavi povišana telesna temperatura ali okužba). Perforacija v prebavilih: V klinicˇnih študijah so porocˇali o perforacijah v prebavilih, v obdobju trženja pa o smrtnih primerih perforacij v prebavilih. Krizotinib je treba pri bolnikih s tveganjem za nastanek perforacije v prebavilih uporabljati previdno; bolniki, pri katerih se razvije perforacija v prebavilih, se morajo prenehati zdraviti s krizotinibom; bolnike je treba poucˇiti o prvih znakih perforacije in jim svetovati, naj se nemudoma posvetujejo z zdravnikom. Vplivi na vid: Opažali so motnje vida; cˇe so trdovratne ali se poslabšajo, je treba razmisliti o oftalmološkem pregledu. Histološka preiskava, ki ne nakazuje adenokarcinoma: Na voljo so le omejeni podatki pri NSCLC, ki je ALK pozitiven in ima histološke znacˇilnosti, ki ne nakazujejo adenokarcinoma, vkljucˇno s skvamoznocelicˇnim karcinomom (SCC). Medsebojno delovanje z drugimi zdravili in druge oblike interakcij: Zdravila, ki lahko povecˇajo koncentracije krizotiniba v plazmi (atazanavir, indinavir, nel.navir, ritonavir, sakvinavir, itrakonazol, ketokonazol, vorikonazol, klaritromicin, telitromicin, troleandomicin), tudi grenivke in grenivkin sok. Zdravila, ki lahko zmanjšajo koncentracije krizotiniba v plazmi (karbamazepin, fenobarbital, fenitoin, rifabutin, rifampicin, šentjanževka). Zdravila, katerih koncentracije v plazmi lahko krizotinib spremeni (midazolam, alfentanil, cisaprid, ciklosporin, derivati ergot alkaloidov, fentanil, pimozid, kinidin, sirolimus, takrolimus, bupropion, efavirenz, peroralni kontraceptivi, raltegravir, irinotekan, mor.n, nalokson, digoksin, dabigatran, kolhicin, pravastatin, metformin, prokainamid). Zdravila, ki podaljšujejo interval QT ali ki lahko povzrocˇijo Torsades de pointes (kinidin, disopiramid, amiodaron, sotalol, dofetilid, ibutilid, metadon, cisaprid, moksi.oksacin, antipsihotiki). Zdravila, ki KRIZOTINIB povzrocˇajo bradikardijo (verapamil, diltiazem, antagonisti adrenergicˇnih receptorjev beta, klonidin, guan.cin, digoksin, me.okin, antiholinesteraze, pilokarpin). Plodnost, nosecˇnost in dojenje: Ženske v rodni dobi se morajo izogibati zanositvi. Med zdravljenjem in najmanj 90 dni po njem je treba uporabljati ustrezno kontracepcijo (velja tudi za moške). Zdravilo lahko škoduje plodu in se ga med nosecˇnostjo ne sme uporabljati, razen cˇe klinicˇno stanje matere ne zahteva takega zdravljenja. Matere naj se med jemanjem zdravila dojenju izogibajo. Zdravilo lahko zmanjša plodnost moških in žensk. Vpliv na sposobnost vožnje in upravljanja s stroji: Lahko se pojavijo simptomatska bradikardija (npr. sinkopa, omotica, hipotenzija), motnje vida ali utrujenost; potrebna je previdnost. Neželeni ucˇinki: Najresnejši neželeni ucˇinki so hepatotoksicˇnost, ILD/pnevmonitis, nevtropenija in podaljšanje intervala QT. Najpogostejši neželeni ucˇinki (. 25 %) so motnje vida, navzea, diareja, bruhanje, edem, zaprtje, povecˇane vrednosti transaminaz, pomanjkanje apetita, utrujenost, omotica in nevropatija. Ostali zelo pogosti (. 1/10 bolnikov) neželeni ucˇinki so: nevtropenija, anemija, levkopenija, disgevzija, bradikardija, bolecˇina v trebuhu in izpušcˇaj. Nacˇin in režim izdaje: Predpisovanje in izdaja zdravila je le na recept, zdravilo pa se uporablja samo v bolnišnicah. Izjemoma se lahko uporablja pri nadaljevanju zdravljenja na domu ob odpustu iz bolnišnice in nadaljnjem zdravljenju. Imetnik dovoljenja za promet: P.zer Limited, Ramsgate Road, Sandwich, Kent, CT13 9NJ, Velika Britanija. Datum zadnje revizije besedila: 23.11.2015 Pred predpisovanjem se seznanite s celotnim povzetkom glavnih znacˇilnosti zdravila. Vir: 1. Povzetek glavnih znacˇilnosti zdravila Xalkori, 23.11.2015 XAR-02-16 Samo za strokovno javnost P.zer Luxembourg SARL, GRAND DUCHY OF LUXEMBOURG, 51, Avenue J.F. Kennedy, L-1855, P.zer podružnica Ljubljana, Letališka cesta 3c, 1000 Ljubljana